Molecular biology is a branch of science which studies biological systems at a molecular level. The purview of molecular biology often overlaps with fields such as biochemistry and genetics, since molecular biology closely studies cell systems and their complex interactions. Protein biosynthesis, DNA, and RNA patterns are also explored by molecular biologists.
- Molecular Biology: A description of molecular biology.
- A Molecular Biology Glossary: Provides terms and definitions related to a number of diagrams.
- Molecular Biology in Marine Science: Scientific questions, technological approaches, and practical implications.
History of Molecular Biology
The name molecular biology was coined in 1938 by Warren Weaver of the Rockefeller Foundation’s Natural Sciences department. Though studies in molecular biology started as early as the 1930’s, it was not until the 1950’s that major strides were taken in the field. The Rockefeller institute helped popularize molecular biology by funding several molecular biology research projects. The advances in X-ray crystallography contributed greatly to the filed of molecular biology as well. In the 1960’s, biologists finally succeeded in isolating, characterizing, and even manipulating molecular cell components such as DNA.
- Molecular Biology History: A brief history of cell and molecular biology.
- The Early History of Molecular Biology: More about the origins of molecular biology.
- Genetics and Molecular Biology: Timeline of the history of genetics and molecular biology.
- Warren Weaver: Contains correspondence, published papers, official documents by Warren Weaver.
- Cell Biology: Introduction and history of cell biology and molecular biology.
- Molecular Biology Evolution: The evolution of molecular biology into systems biology.
- Brief History of Molecular Biology: A brief history of the molecular biology and genetics of cyanobacterial toxicity.
The Central Dogma of Molecular Biology
In 1958, Francis Crick articulated the central dogma of molecular biology. Subsequently, he re-stated the central dogma in 1970. The central dogma explains the sequential information transfer in terms of detailed residue transfer. It also states that information cannot be re-transferred from protein to nucleic acid or protein. To better understand the framework of sequential information transfers comprising of biopolymers, the central dogma is often used. The central dogma also categorizes the biopolymers into three groups, namely the DNA, RNA, and the proteins. Furthermore, the central dogma further sub-divides the groups into three classes: the 3 general transfers, the three special transfers, and the three unknown transfers.
- The Central Dogma: The original paper by Francis Crick.
- Francis Crick: His biography at the official Nobel Prize website.
- DNA: Describes the discovery of DNA.
- Coral Genomics: The principal statement of molecular biology is described from the perspective of coral genomics.
- Microarrays Central Dogma: A lecture on the central dogma of molecular biology.
- Molecular Biology Basics: Explains the central dogma of molecular biology.
Molecular Biology Techniques
There are a number of important molecular biology techniques which help scientists to isolate or manipulate the molecular cell components.
- Expression Cloning – This method is considered a basic technique for studying protein functions. In this technique, the protein’s DNA coding is cloned into an expression vector called a plasmid. This plasmid may or may not contain promoter elements for producing protein of interest.
Expression Cloning: Expression cloning of a rat B2 bradykinin receptor.
- Polymerase Chain Reaction – This technique is used for DNA copying since it’s very versatile. In PCR, a DNA sequence can be easily copied thousands of times or can even be altered.
Polymerase Chain Reaction: A comprehensive PCR and Multiplex PCR Guide.
- Gel Electrophoresis – This technique is based on the premise that electric fields can separate proteins, DNA, and RNA molecules. The agarose gel electrophoresis is the technique wherein agarose gel is used to separate RNA and DNA.
Gel Electrophoresis Virtual Lab: How gel electrophoresis is used in forensics.
- Southern Blotting – Southern Blotting is the technique for finding out a particular DNA sequence which is present in a DNA sample. After the DNA samples are separated by gel electrophoresis, they are passed on to a membrane by blotting.
Southern Blot Method: A brief overview of a Southern Blot technique.
- Northern Blotting – The northern blotting technique helps in the better understanding of a specific RNA molecule’s expression patterns.
Northern Blot Technique: Details RNA processing and the Northern Blot technique.
- Western Blotting – In western blotting, small amounts of protein are injected into animal specimens such as a mouse, creating the antibodies of the proteins. When produced by using animals as agents, they are called polyclonal antibodies and when produced in a cell culture, they’re known as monoclonal antibodies.
Western Blotting: An introduction to Western Blot activity.
- Eastern Blotting – A protein’s post-translational modification can be identified by the eastern blotting technique. A few specific substrates are used for probing the modifications of the blotted proteins.
Additional Information and Techniques
- DNA Fingerprinting: Explains the techniques of molecular biology.
- Techniques: More on techniques from the Advanced Molecular Biology Techniques Laboratory.
- Molecular Techniques: Discusses specific techniques of molecular genetics.
- Molecular Biology Resources: Techniques, tips, and questions concerning molecular biology.
- Agarose Gel: More on Agarose Gel Electrophoresis of DNA.
- PCR: Advantages and limitations of quantitative PCR.
If you find this article useful, please free feel to link or reuse it. All we ask is for a credit back to our site.