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6.1: Prokaryotic gene regulation

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    25747
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    Learning Objectives

    • Define operon and describe how it differs from genes organized by single proteins.
    • Identify the functions of regulatory proteins, promoters, operators, cis- and trans-acting factors, and structural genes.
    • Distinguish between positive vs negative and inducible vs repressible operons.
    • Identify and understand the role of the structure and components of the lac operon and predict whether or not gene expression will occur under particular conditions.

    Early insights into mechanisms of transcriptional regulation came from studies of E. coli by researchers Francois Jacob & Jacques Monod. In E. coli, and many other bacteria, genes encoding several different proteins may be located on a single transcription unit called an operon. The genes in an operon share the same transcriptional regulation, but are translated individually. Eukaryotes generally do not group genes together as operons (though there are some exceptions including C. elegans and a few other species).

    How can an operon encode multiple proteins?

    Think back to the steps involved in transcription and translation. Which steps will be altered if multiple proteins must be translated from a single transcript? How do you think this works?

    Types of regulation

    Operons can be turned "off" (repressible) or "on" (inducible) and be controlled protein activators or repressors.

      Inducible regulation turns transcription ON. Repressible regulation turns transcription OFF.
    Positive regulation uses activator proteins. An activator protein turns ON transcription in response to a stimulus / condition. An activator protein is inactivated in response to a stimulus / condition, turning transcription OFF.
    Negative regulation uses repressor proteins. A repressor protein is inactivated in response to a stimulus / condition, turning transcription turns ON. A repressor protein turns transcription turns OFF in response to a stimulus / condition.

    Basic lac operon structure

    E. coli encounters many different sugars in its environment. These sugars, such as lactose and glucose, require different enzymes for their metabolism. Three of the enzymes for lactose metabolism are grouped in the lac operon: lacZ, lacY, and lacA. LacZ encodes an enzyme called β-galactosidase, which digests lactose into its two constituent sugars: glucose and galactose. lacY is a permease that helps to transfer lactose into the cell. Finally, lacA is a trans-acetylase. Transcription of the lac operon normally occurs only when lactose is available for it to digest. Presumably, this avoids wasting energy in the synthesis of enzymes for which no substrate is present. A single mRNA transcript includes all three enzyme-coding sequences and is called polycistronic. A cistron is equivalent to a gene.

    Fig12.2.png
    Figure \(\PageIndex{1}\): Diagram of a segment of an E. coli chromosome containing the lac operon, as well as the lacI coding region. The various genes and cis-elements are not drawn to scale. (Original-Deyholos-CC:AN)

    cis- and trans- Regulatory Elements

    The lac operon includes DNA sequences that do not encode proteins, but are instead binding sites for proteins that regulate transcription of the operon. In the lac operon, these sequences are called P (promoter), O (operator), and CBS (CAP-binding site). Collectively, sequence elements such as these are called cis-elements because they must be located on the same piece of DNA as the genes they regulate. On the other hand, the proteins that bind to these cis-elements are called trans-regulators because (as diffusible molecules) they do not necessarily need to be encoded on the same piece of DNA as the genes they regulate.

    lacI is an allosterically regulated repressor

    One of the major trans-regulators of the lac operon is encoded by lacI. Four identical molecules of lacI proteins, encoded by a gene distinct from the operon that encodes lacZ, lacY, and lacA, assemble together to form a homotetramer called a repressor. This repressor binds to two operator sequences adjacent to the promoter of the lac operon. Binding of the repressor prevents RNA polymerase from binding to the promoter. Therefore, the operon will not be transcribed when the operator is occupied by a repressor.

    Allosteric regulation occurs when a substrate causes a change to the structure and function of a protein. In this example, in addition to domains that bind operator seqeucnes in DNA, lacI protein has sites that bind to allolactose, which is a small molecule produced when lactose is present. When allolactose is bound to lacI, the shape of the protein changes and prevents it from binding to the operator. Therefore, in the presence of lactose, RNA polymerase is able to bind to the promoter and transcribe the lac operon, leading to a moderate level of expression of the lacZ, lacY, and lacA genes.

    Fig12.4.png
    Figure \(\PageIndex{2}\): When the concentration of lactose [Lac] is low, lacI tetramers bind to operator sequences (O), thereby blocking binding of RNApol (green) to the promoter (P). Alternatively, when [Lac] is high, allolactose binds to lacI, preventing the repressor from binding to O, and allowing transcription by RNApol. (Origianl-Deyholos-CC:AN)

    CAP is an allosteric activator of the lac operon

    A second aspect of lac operon regulation is conferred by a trans-factor called cAMP binding protein (CAP). CAP is another example of an allosterically regulated trans-factor. Only when the CAP protein is bound to cAMP can another part of the protein bind to a specific cis-element within the lac promoter called the CAP binding sequence (CBS). CBS is located very close to the promoter (P). When CAP is bound to at CBS, RNA polymerase is better able to bind to the promoter and initiate transcription. Thus, the presence of cAMP ultimately leads to a further increase in lac operon transcription.

    Fig12.5.png

    Figure \(\PageIndex{3}\): CAP, when bound to cAMP, helps RNApol to bind to the lac operon. cAMP is produced only when glucose [Glc] is low. (Origianl-Deyholos-CC:AN)

    The physiological significance of regulation by cAMP becomes more obvious in the context of the following information. The concentration of cAMP is inversely proportional to the abundance of glucose: when glucose concentrations are low, an enzyme called adenylate cyclase is able to produce cAMP from ATP. Evidently, E. coli prefers glucose over lactose, and so expresses the lac operon at high levels only when glucose is absent and lactose is present. This provides another layer of logical control of lac operon expression: only in the presence of lactose, and in the absence of glucose is the operon expressed at maximal levels.

    Fig12.6a.png Fig12.6b.png
    Figure \(\PageIndex{4}\): When glucose [Glc] and lactose [Lac] are both high, the lac operon is transcribed at a moderate level, because CAP (in the absence of cAMP) is unable to bind to its corresponding cis-element (yellow) and therefore cannot help to stabilize binding of RNApol at the promoter. Alternatively, when [Glc] is low, and [Lac] is high, CAP and cAMP can bind near the promoter and increase further the transcription of the lac operon. (Origianl-Deyholos-CC:AN)

    Video Summary of the lac operon

    Video \(\PageIndex{1}\): Prokaryotic Gene Regulation: Lac Operon. (AMBOSS: Medical Knowledge Distilled via https://youtu.be/-4Jr84qyKPo)

    Contributors and Attributions


    This page titled 6.1: Prokaryotic gene regulation is shared under a CC BY-SA license and was authored, remixed, and/or curated by Stefanie West Leacock.