Energy and Metabolism

August 8th, 2011 by admin No comments »

An Intro Into Energy and Metabolism

Any organism is nothing more than a series of chemical reactions – some related and some not related. The sum of all of these reactions – the organism’s metabolism – is very integral in maintaining the specific organism. We should think of organisms as being billions of chemically complex reactions. There are two classifications of reactions that occur within living organisms: catabolic reactions are reactions that break down complex molecules into much simpler molecules – anabolic reactions are reactions that create complex molecules from much simpler molecules.

Energy and the Laws that Govern It

There are various forms of energy within the universe, and regardless of the state in which the energy appears, it still is under subtle laws. The First Law of Thermodynamics states that energy cannot be created or destroyed – energy can only change form as it passes through various systems. The Second Law of Thermodynamics states that entropy (disorder) in the universe is always increasing.

Why Is Energy Important?

Energy must be present to complete reactions that naturally exist as non-spontaneous. A spontaneous reaction does not require additional energy (from an outside source) to proceed – a non-spontaneous reaction does require this help. Regardless of whether or not a reaction is spontaneous (exergonic) or non-spontaneous (endergonic), an activated complex must be attained by supplying the reaction with the correct amount of activation energy.

ATP

ATP (adenosine triphosphate) is closely related to one type of nucleotide found in nucleic acids – ATP has the nitrogenous base, adenine, bonded to ribose (just like in RNA – except that ATP has three phosphates). The bonds between the phosphate groups of ATP’s tail can be broken by hydrolysis (using water to break the bond – a type of catabolic reaction). When the ATP is hydrolyzed (it is now ADP), energy is released – this reaction has a free energy value deltaG = -31kj/mol (-7.3kcal/mol). Please note that this deltaG value is negative – which means that this reactions occurs spontaneously. Therefore, we can consider the phosphate bonds on ATP to have an ability to create a substantial amount of energy if ATP is hydrolyzed.

ATP is usually depleted very quickly – not to worry, ATP can be regenerated very quickly. In this backwards reaction, ADP can combine with an inorganic phosphate group – the energy required to complete this anabolic reaction generally comes from catabolism of organic nutrients.

Coupling Reactions

There are many reactions that are non-spontaneous – in other words, such reaction cannot proceed without an input of energy. Many times, such a reaction is coupled (placed with) a reaction that is highly spontaneous (ATP hydrolysis). Coupling reactions in this method helps reactions that would not usually proceed to proceed.

Enzymes

Enzymes are catalytic proteins – agents that help to speed up the rates of various reactions without being consumed in the reaction. They are able to be successful with this increase in speed because they are able to lower the activation energy required to reach the transition state of the molecules. Note that without enzymes, a reaction would require more energy to attain the required transition state. When an enzyme is used, neither the equilibrium concentrations nor the energy released by the reaction changes.

Enzymes are proteins and are only able to help speed up reactions because of their specific interactions to the substrate – the actual reactant in the molecule.

For the above reaction, it proceeds very slowly without an enzyme – however, once the enzyme sucrase is added in the reaction vessel, the reaction proceeds very quickly. Note that the substrate, sucrose, has been broken down at the end of the reaction.

Most enzymes are proteins – which have specific three-dimensional shapes (conformations) that give them their unique and precise ability to bond accurately with their specific substrate. It can be assumed that only one enzyme can catalyze one specific substrate.

The substrate bonds to the enzyme at the active site – the region of the protein that usually appears as a pocket or groove. The specificity of an enzyme is attributed to a compatible fit between the shape of its active site and shape of the substrate. This specificity is known as the lock and key model. » Read more: Energy and Metabolism

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An Amazing Way to Get Organisms With Characteristics of Your Choice!

August 8th, 2011 by admin No comments »

When you think of god’s creation, a thought may come that if it were in your hands to choose the characteristics of an organism. You would definitely not miss such a chance. Well, you can’t do it at home! Many schools of thought had worked on it successfully.

What is transformation? : The uptake of DNA by the bacterial cells is called transformation. DNA is said to be the genetic material of living organisms. It determines the characteristics of an organism. DNA contains genes. Each gene is responsible for a single characteristic. Hence if the desired part of DNA is transformed into the bacterial cells, we get the organism with characteristic of our choice.

Transformation of individual cells:

  • With most organisms the main barrier to DNA uptake is the cell wall. The animal cells grown artificially in the lab, which usually lack cell walls, are easily transformed. Especially when the DNA is already precipitated onto the cell surface by calcium phosphate treatment.
  • For other types of cells the answer to this is to remove the cell wall. Enzymes that degrade yeast, fungal and plant cell walls are available and under the right conditions intact protoplasts (cell without a cell wall) can be obtained. Protoplasts generally take up DNA quite readily, but transformation can be stimulated by special techniques.

Electroporation: in this technique, the cells are subjected to a short electric pulse, thought to induce the transient formation of pores in the cell membrane, through which the DNA molecules are able to enter the cell. After transformation the protoplasts are washed to remove the degradative enzymes and the cell wall spontaneously re-forms.

Other two physical methods:

1. Microinjection: it makes use of a very fine pipette to inject DNA molecules directly into the nucleus of the cells to be transformed. This technique was initially applied for animal cells but has subsequently been successful with plant cells.

2. Bombardment:this technique involves bombardment of the cells with high velocity microprojectiles, usually particles of gold or tungsten that have been coated with DNA. These microprojectiles are fired at the cells from a particle gun. This unusual technique is termed as biolistics and has been used with a number of different cell types.

Transformation of whole organisms:

With animals and plants the desired product may not be transformed cells, but a transformed organism. Plants are relatively easy to regenerate from cultured cells, though problems have been experienced in developing regeneration procedures for monocotyledonous species such as cereals and grasses. A single transformed plant cell can therefore give rise to a transformed plant, which carries the cloned DNA in every cell, and passes the cloned DNA to its progeny following flowering and seed formation. » Read more: An Amazing Way to Get Organisms With Characteristics of Your Choice!

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