The Nature of DNA in a Given Organism

Introduction

Genetic information in the form of the sequence of nucleotide triplets in the DNA determines the structure and functions of cells by specifying the nature of the proteins present in the cell. The process is done by two steps which are now reasonably well understood. In the first step, the nucleotide sequence from one of the two DNA stranded is transcribed on to mRNA, hence this process is known as transcription. The newly transcribed mRNA is complementary to one of the DNA that served as its template. The process is known as transcription. In the second step, the mRNA sequence is converted into specific sequences of amino acids in proteins where triplet bases of the mRNA coded for each individual amino acid. This latter process is known as translation.

Gene expression determines the state of differentiation of the cell and has role in the regulation of cell activity in various physiological states. Gene activation and repression caused by differentiation is stable and inheritable. When gene expression is controlled by physiological signal, it is transient and easily reversed. Despite these differences, many of the events surrounding these two different kinds of regulation by gene expression are common.

Cells at different periods during the life cycle may differ significantly in structure and function. In fact, the multicellular organisms possess different type of cells. Each type specialized to perform a specific duty. These cells are said to be differentiated. The different types of cells differ from each other in that each type expresses only a small portion of the genetic information of the genome. Through the differentiation, part of the genome has been lost, though it is not generally.

Gene Expression : Genotype and Phenotype

The DNA of an organism is very long double-stranded helical molecule made up of linear series of molecular units called nucleotides, of which there are four types: Adenine, Guanine, Cytosine, and Thymine. Genes comprise specific segments of this DNA, and the sequences of nucleotides within a gene constitutes a code which specifies the order of amino acids in the proteins that are building blocks of tissues and cells, as well as the enzyme and hormones that allow metabolism to proceed. Each gene specifies the construction of different protein. Enzyme plays an important role of physiological processes in a biochemical reaction of an organism. Due to most of the metabolism activity in an organism are catalyzed by enzyme. The product of metabolism is being used to grow and develop the cell. However, a problem arises if the nature or arrangement of the nucleotides in gene is altered. An aberrant amino acid sequence may be specified in the particular protein that arises from such a modified or mutated gene and in turn, this variant protein may have serious consequences to the organism.

Nucleotide sequences in DNA, however, do not encode proteins. Many sequences lying outside the coding segments of genes form part of the machinery that can adjust the activity of specific genes. Not only do nucleotide sequences in the DNA of an organism determine precisely the type and structure of proteins that an organism will make, but they also comprise part of the signaling machinery that controls the level to which these proteins are produced by the organism in response to environmental conditions.

Another important feature of DNA molecule is their ability to serve as templates for the manufacture of copies them selves. When cells divide and when egg and sperm cells are produced, each progeny cell has a complete set of genes which are virtually identical to the set in the original cells. Although not completely error free, this DNA replication process forms the basis whereby nucleotide sequence variations within genes and related DNA segments are inherited.

While an organism‘s complement of genes (genotype) sets its potential, the properties actually realized (phenotype) depends on the interactions of all of these genes with the environment. An organism’s phenotype unfolds during development and maturation when genes and the products derived from them, interact with one another and with environmental factors, made a morphological characteristic of an organism. A trait cannot be attributed solely to genes or to the environment, since an organism requires an inter play of both for successful survival. Genes provide the initial guidelines for the development of an organism, and a range of possible phenotypes. Within that predetermined range, a specific phenotype is molded by environmental influences. When one is dealing with very complex characteristics such as behavior, the interactions between heredity and environment are far too complicated to be understood at this time. Nevertheless, there are inherited to have a behavioral component as part of their phenotype.

Even if gene is present in an individual organism or cell, it may not be active, or switched-up. Moreover, the number of copies of proteins produced per unit time by different genes varies to satisfy cellular requirements. Many gene products are needed only under certain conditions, and regulatory mechanisms that function like an on-off switch allow such products to be made only when required. Other more refined mechanisms can make minor adjustment in the intracellular concentration of a particular protein in response to needs imposed by the environment. On the other hand, when a gene is active, its protein product has the potential to interact with other elements within the environment of the cells as well as with external environmental factor such as dietary components temperature.

The interaction between the organism and environment are complex, but crucial to these are the precise molecular effect of environmental factor in relation to the DNA of genes. Such interactions are of reaching significance for the mechanisms of adaptation, acclimation, and evolution. It is also clear that they are very relevant to the development of important organism degenerative diseases and to processes that contribute the ageing.

A specific class of genes can be activated to yield special protein that is used to protect vital cellular structure from environment adversity. In relation to gene activity they are may layers of feedback regulation from both the physiology of the organism itself and the external environment. Certain types of stressful environmental conditions can activate stress gene to produce stress protein that enable organisms to tolerate such stresses.

References

Anonim. 2006. E-book : Chapter 03, Gene Expression in Differentiated Cells.pdf.

            http://albany/edu/03 part1.html.

Burdon, R. H. 1999. Genes and The Environment. University of Stratclyde. Scotland

Campbell, NA., and J.B. Reece. 2005. Biology. Pearson Education, Inc. San Francisco.

Tri Wibowo, Y. 2005. Biologi Molekular. Erlangga. Jakarta.