Introduction

Figure 16.1 The genetic content of each somatic cell in an organism is the same, but not all genes are expressed in every cell. The control of which genes are expressed dictates whether a cell is (a) an eye cell or (b) a liver cell. It is the differential gene expression patterns that arise in different cells that give rise to (c) a complete organism.

Chapter Outline

16.1 Regulation of Gene Expression

16.2 Prokaryotic Gene Regulation

16.3 Eukaryotic Epigenetic Gene Regulation

16.4 Eukaryotic Transcriptional Gene Regulation

16.5 Eukaryotic Post-transcriptional Gene Regulation

16.6 Eukaryotic Translational and Post-translational Gene Regulation

16.7 Cancer and Gene Regulation

Most people know that regular exercise is important to maintain good health. It promotes cardiovascular health and helps to prevent obesity. Scientists have now discovered that long-term endurance training also changes how genes are expressed in muscle tissue. In a recent study, 23 healthy people each exercised one leg for 45 minutes four days a week while resting the other leg. After three months, muscles from participants’ legs were biopsied, and scientists analyzed the activity level of over 20,000 genes in the tissue samples.

They found that for each participant the exercised leg had reduced inflammation and improved metabolism compared with the non-exercised leg. These differences were accompanied by changes in genes associated with metabolism and inflammation. However, the actual nucleotide sequences of the genes weren’t changed. Instead, some genes were methylated, which simply means methyl groups were attached to certain nucleotides along the sequence. This, essentially, turned the genes “off” or otherwise changed how they were expressed. DNA methylation is an example of epigenetics, which is a process that alters genes without affecting the nucleotide sequence of the genes.