Fact-checked by Grok 2 weeks ago

Repressor

A repressor is a protein that inhibits gene expression by binding to specific DNA sequences, such as promoters or operators, thereby preventing or reducing the transcription of messenger RNA from the associated gene.^[1] This regulatory mechanism is essential for controlling cellular responses to environmental signals and maintaining metabolic balance.^[2] In prokaryotes, repressors typically function through negative regulation by binding to an operator sequence near the promoter of an operon—a cluster of co-regulated genes—thus blocking RNA polymerase from initiating transcription.^[2] For instance, in the lac operon of Escherichia coli, the lac repressor (encoded by the lacI gene) binds the operator in the absence of lactose, repressing genes involved in lactose metabolism; the presence of an inducer like allolactose alters the repressor's conformation, releasing it from the DNA and allowing expression.^[2] Similarly, the trp repressor in the tryptophan operon binds the operator only when activated by tryptophan, providing negative feedback to halt unnecessary amino acid synthesis.^[2] These ligand-dependent interactions demonstrate how prokaryotic repressors can undergo conformational changes upon binding small molecules, enabling precise control.^[2] In eukaryotes, gene regulation by repressors is more complex, where DNA-binding proteins can act as either repressors or activators depending on the cellular context or interactions with other proteins.^[1] Additionally, non-coding RNAs can serve repressive roles by interfering with transcription or mRNA stability, expanding the regulatory toolkit beyond proteins.^[1] Repressors thus play a critical role across all domains of life in fine-tuning gene expression to adapt to developmental cues, stress, and nutrient availability.^[3]

Definition and Basics

Definition

A repressor is a DNA- or RNA-binding protein that inhibits gene expression by preventing the transcription of specific genes.^[1] It achieves this by binding to operator sites or promoter regions in the DNA, thereby blocking the access of RNA polymerase to the transcription start site or interfering with the recruitment of transcriptional machinery.^[4] In some cases, repressors may also interact with co-repressor molecules to enhance their inhibitory effect.^[3] Repressors play a fundamental role in negative regulation of gene expression, functioning as molecular switches that fine-tune cellular responses to environmental cues.^[5] They typically respond to signals such as metabolite concentrations, where the presence or absence of a ligand modulates the repressor's binding affinity to its target DNA sequence, thereby controlling the timing and level of gene transcription.^[6] This regulatory mechanism ensures efficient resource allocation in cells by suppressing unnecessary gene activity until required.^[7] In contrast to activators, which promote transcription by facilitating RNA polymerase recruitment or stabilizing the transcription initiation complex, repressors specifically downregulate gene expression through steric hindrance or active interference.^[2] Repressors can be classified as inducible, where an effector molecule induces a conformational change that releases the repressor from DNA, or constitutive, where repression occurs continuously without such modulation.^[8] This distinction highlights their versatility in maintaining dynamic control over genetic output.^[9]

Historical Discovery

The concept of the repressor emerged in 1961 when François Jacob and Jacques Monod proposed the operon model for gene regulation in bacteria, introducing the idea of a repressor protein produced by a regulatory gene that binds to an operator site to prevent transcription of structural genes unless modulated by inducers or corepressors.^[10] This model, developed through studies on the lac operon in Escherichia coli, provided the first framework for negative control in prokaryotic gene expression and revolutionized understanding of how cells respond to environmental signals.^[11] A pivotal experimental milestone came in 1966 with the isolation of the lac repressor protein by Walter Gilbert and Benno Müller-Hill, who employed a nitrocellulose filter-binding assay to detect and purify the molecule from E. coli extracts, confirming its role in binding the operator DNA sequence and demonstrating the physical basis of Jacob and Monod's hypothesis. Shortly thereafter, in 1967, Mark Ptashne isolated the λ phage repressor using similar techniques, further validating the repressor mechanism in viral gene control.^[12] These achievements built on foundational genetic work, earning Jacob, Monod, and André Lwoff the 1965 Nobel Prize in Physiology or Medicine for discoveries concerning the genetic control of enzyme and virus synthesis.^[13] The understanding of repressors expanded beyond prokaryotes in the 1980s, as researchers identified eukaryotic counterparts, notably steroid hormone receptors that function as ligand-activated transcription factors capable of repressing gene expression by recruiting corepressors to target promoters or interfering with activator binding.^[14] Cloning of receptors such as the glucocorticoid and estrogen receptors during this period revealed their modular structures and repressive activities, marking a shift toward recognizing conserved regulatory principles across kingdoms.^[15]

Molecular Structure and Function

Protein Structure

Repressor proteins are modular polypeptides characterized by distinct structural domains that facilitate their regulatory roles in gene expression. The core architecture typically includes a DNA-binding domain (DBD) responsible for sequence-specific recognition of operator or silencer sites in DNA. In prokaryotic repressors, the DBD often features a helix-turn-helix (HTH) motif, consisting of two alpha-helices connected by a short turn, where the recognition helix inserts into the major groove of DNA to make base-specific contacts.^[16] Eukaryotic repressors frequently employ zinc finger domains, which utilize zinc ions to stabilize finger-like loops that interact with DNA, enabling precise binding through multiple fingers arranged in tandem.^[17] These DBDs are usually located at the N-terminus and are essential for targeting repressor activity to specific genomic loci. Adjacent to the DBD is the ligand-binding domain (LBD), which serves as an allosteric site for small-molecule effectors such as metabolites or inducers. The LBD undergoes conformational changes upon effector binding, which can either stabilize or disrupt the protein's interaction with DNA, thereby modulating repression.^[18] This allosteric mechanism is mediated by structured pockets within the LBD that accommodate ligands, often leading to rigid-body movements or hinge-like flexing between domains to propagate signals across the protein.^[19] Such sites are prevalent in metabolite-sensing repressors, allowing cells to fine-tune gene expression in response to environmental cues without altering protein levels. Many repressor proteins enhance their DNA-binding affinity and specificity through oligomerization, forming dimers, tetramers, or higher-order assemblies via dedicated interfaces. Leucine zipper motifs, characterized by amphipathic alpha-helices with conserved leucine residues at every seventh position, mediate dimerization by interlocking like a zipper, positioning multiple DBDs for cooperative DNA engagement.^[18] Other oligomerization domains, such as beta-sheets or coiled-coils, similarly promote multimeric states that increase avidity for DNA targets, a structural feature conserved across diverse repressor families.^[19]

Binding Mechanisms

Repressors inhibit gene transcription by binding to specific DNA sequences known as operators, typically located near promoter regions. This binding occurs through sequence-specific interactions, where the repressor's DNA-binding domain recognizes and contacts particular nucleotide bases, often inserting alpha helices into the major groove of the DNA double helix to achieve high specificity. For instance, the lac repressor protein binds its operator with an exceptionally high affinity, characterized by a dissociation constant (Kd) of approximately $10^{-13} M, enabling tight regulation even at low cellular concentrations.90276-0) Such interactions are mediated by hydrogen bonds, van der Waals forces, and electrostatic contacts between amino acid side chains and DNA bases, ensuring selective recognition amid vast non-specific DNA sequences.00392-6) Many repressors function as allosteric proteins, where binding of effector molecules at a site remote from the DNA-binding domain induces conformational changes that modulate operator affinity. In the case of the lac repressor, the gratuitous inducer isopropyl β-D-1-thiogalactopyranoside (IPTG) binds to the core domain, triggering a structural rearrangement that reorients the N-terminal DNA-binding domains relative to the dimer interface. This shift disrupts key interactions necessary for operator recognition, reducing binding affinity by several orders of magnitude and releasing the repressor from DNA.^[20] Allosteric regulation thus allows environmental signals, such as metabolite availability, to dynamically control repressor activity without altering protein levels. Upon binding to the operator, repressors primarily exert their inhibitory effect through steric hindrance, physically obstructing RNA polymerase from accessing the promoter or initiating transcription. In prokaryotic systems, the bound repressor occupies space that overlaps with the RNA polymerase binding site, preventing promoter recognition, isomerization, or open complex formation required for transcription start. This mechanism does not involve covalent modifications to DNA or associated proteins, relying instead on the spatial exclusion of the large RNA polymerase holoenzyme.^[21] For example, in the lac operon, the repressor-bound operator directly blocks the path for RNA polymerase progression, ensuring repression until inducer-mediated dissociation occurs.00180-6)

Types and Mechanisms of Repression

Prokaryotic Repressors

Prokaryotic repressors are regulatory proteins that play a central role in controlling gene expression in bacteria by binding to operator sequences on DNA, thereby inhibiting the transcription of downstream genes organized into operons. Operons consist of clusters of functionally related genes transcribed as a single polycistronic mRNA from a shared promoter, allowing coordinated regulation of pathways such as nutrient metabolism. In response to environmental nutrients like amino acids or sugars, repressors modulate the synthesis of this mRNA to optimize cellular resource allocation, ensuring that genes for catabolic or biosynthetic processes are expressed only when necessary.^[22] Prokaryotic operons are classified into inducible and repressible types based on how repressors interact with small molecules to control transcription. In inducible operons, the repressor is active in the absence of an inducer, binding the operator to block RNA polymerase and prevent mRNA synthesis; binding of an inducer molecule causes a conformational change in the repressor, releasing it from the DNA and allowing transcription. Conversely, in repressible operons, the repressor is inactive without a corepressor and does not bind the operator under normal conditions, permitting constitutive transcription; accumulation of a corepressor, such as an end product of the pathway, activates the repressor by altering its structure, enabling it to bind the operator and halt mRNA production. This distinction enables bacteria to fine-tune gene expression: inducible systems respond to the presence of substrates, while repressible systems shut down when products are abundant.^[23] Global regulation in prokaryotes can also involve activators whose inactivity leads to repression, coordinating expression across multiple operons and integrating signals from cellular metabolism to prioritize energy-efficient pathways. A key example is catabolite repression mediated by the cyclic AMP receptor protein (CRP) complex, which activates transcription of operons for alternative carbon sources only when preferred nutrients like glucose are unavailable. Low intracellular cAMP during glucose metabolism prevents formation of the active CRP-cAMP complex, inhibiting transcription of numerous catabolic operons and thereby enforcing repression to favor efficient glucose utilization. CRP influences over 180 genes in Escherichia coli, demonstrating its role as a master regulator that links nutrient sensing to broad-scale gene control.^[24]^[25]

Eukaryotic Repressors

In eukaryotes, transcriptional repressors often operate at the chromatin level to enforce gene silencing through modifications that promote nucleosome compaction and restrict access to DNA. Histone deacetylases (HDACs), such as HDAC1 and HDAC2, remove acetyl groups from lysine residues on histone tails, neutralizing their negative charge and facilitating tighter DNA wrapping around histones, which condenses chromatin into a transcriptionally inactive state.^[26] Similarly, histone methyltransferases like SUV39H1/2 catalyze trimethylation of histone H3 at lysine 9 (H3K9me3), recruiting heterochromatin protein 1 (HP1) to propagate compact heterochromatin domains that silence genes over large genomic regions.^[27] These modifications, often coordinated within multiprotein complexes like NuRD (for HDACs) or PRC2 (for H3K27 methylation by EZH2), create stable epigenetic barriers to transcription initiation.^[26]^[27] Eukaryotic repressors also modulate enhancer-promoter interactions to prevent activation of distant regulatory elements. The RE1-silencing transcription factor (REST), for instance, binds to repressor element 1 (RE1) motifs in neuronal gene enhancers, competing with activators and recruiting co-repressors like CoREST and HDAC2 to deacetylate histones at target promoters.^[28] This interference disrupts loop formation between enhancers and promoters, as seen in the repression of genes like the sodium channel Nav1.2, where REST occupancy correlates with reduced mRNA levels and blocked neurite outgrowth in non-neuronal cells.^[28] By integrating with chromatin remodelers, REST ensures cell-type-specific silencing, maintaining the neuronal gene program in a poised, inactive configuration.^[28] Signaling pathways further integrate eukaryotic repression through ligand-dependent recruitment of co-repressors. Unliganded thyroid hormone receptors (TRs), for example, actively repress target genes by binding DNA response elements and associating with nuclear receptor co-repressors (NCoR) via specific interaction domains.^[29] NCoR bridges TR to HDAC-containing complexes like mSin3A-HDAC1, promoting histone deacetylation and chromatin compaction to inhibit basal transcription; upon hormone binding, this complex dissociates, switching to activation.^[29] This mechanism exemplifies how eukaryotic repressors couple extracellular signals to epigenetic silencing, ensuring precise control over developmental and metabolic genes.^[29]

Key Examples

Lac Operon Repressor

The lac repressor, also known as LacI, is encoded by the lacI gene located upstream of the lac operon in Escherichia coli. This gene produces a tetrameric protein consisting of four identical subunits, each with a molecular weight of approximately 38.5 kDa, resulting in a total mass of about 155 kDa for the functional oligomer. The repressor binds with high affinity to specific DNA sequences called operators (primarily O1, but also auxiliary sites O2 and O3) within the lac operon, thereby blocking RNA polymerase access to the promoter and repressing transcription of downstream genes, including lacZ, which encodes the enzyme β-galactosidase essential for lactose metabolism.^[30]^[31] The mechanism of repression is inducible and relies on allosteric regulation. In the absence of lactose, the tetrameric repressor binds tightly to the operator DNA, forming a stable complex that inhibits gene expression. When lactose is present, it is converted to allolactose by β-galactosidase; allolactose acts as the natural inducer by binding to the repressor's core domain, inducing a conformational change that reduces DNA-binding affinity by approximately 1,000-fold and causes the repressor to dissociate from the operator. Synthetic inducers like isopropyl β-D-1-thiogalactopyranoside (IPTG) mimic this effect by binding to the same allosteric site without being metabolized, allowing controlled induction in experimental settings. The equilibrium binding can be represented as:

\text{Repressor} + \text{Operator} \rightleftharpoons \text{Repressor-Operator Complex}

with a dissociation constant K_d \approx 10^{-13} M in the absence of inducer, reflecting the exceptionally tight interaction that ensures effective repression under non-inducing conditions.^[32]^[20]^[30] The purification of the lac repressor in 1966 marked a pivotal advancement, as it was the first genetic regulatory protein isolated in pure form, enabling direct biochemical assays of its interactions. This breakthrough facilitated foundational studies on operator specificity, such as footprinting and competition assays that mapped the minimal operator sequence required for high-affinity binding (approximately 17-21 base pairs centered around the symmetric dyad). Additionally, the availability of purified repressor protein supported mutagenesis experiments on both the lacI gene and operator DNA, revealing key residues in the DNA-binding domain (e.g., helix-turn-helix motif) and operator mutations (e.g., O^c variants) that alter specificity and inducibility, thereby elucidating the molecular basis of negative control in prokaryotes.^[30]^[33]

Trp Operon Repressor

The Trp operon repressor serves as a paradigmatic example of a corepressor-activated regulatory protein in prokaryotic gene expression, controlling the transcription of genes involved in tryptophan biosynthesis in bacteria like Escherichia coli. Encoded by the trpR gene, the repressor is a homodimeric protein with each subunit comprising 107 amino acids and a total molecular mass of approximately 25 kDa. In its inactive aporepressor form, the protein exhibits low affinity for the operator DNA sequence located downstream of the trp promoter. Binding of L-tryptophan, acting as a corepressor, induces a conformational change that transforms the aporepressor into the active holorepressor, enabling high-affinity binding to the operator and thereby repressing transcription initiation by sterically hindering RNA polymerase progression.^[34] Tryptophan binding occurs at the dimer interface, where two molecules of the amino acid occupy symmetric pockets, repositioning flexible helix-turn-helix motifs to align with the major groove of the operator DNA. This allosteric activation dramatically enhances DNA-binding specificity and affinity, increasing it approximately 70-fold, with the dissociation constant (K_d) for the holorepressor-operator complex reaching about 10^{-11} M under physiological conditions. The operator consists of a 18-base-pair palindromic sequence that accommodates the dimeric repressor, forming a ternary complex stabilized by hydrogen bonds and van der Waals interactions between repressor residues and specific base pairs.^[34] In addition to repression at initiation, the Trp repressor functions in synergy with a transcription attenuation mechanism within the trp operon leader region (trpL), which encodes a short peptide rich in tryptophan residues, including two tandem Trp codons. When intracellular tryptophan levels are high, abundant charged tRNA^{Trp} facilitates rapid translation of the leader peptide, allowing the ribosome to cover regions of the nascent mRNA that would otherwise form an antiterminator structure; this promotes formation of a rho-independent terminator hairpin approximately 140 nucleotides downstream of the transcription start site, resulting in premature termination of up to 90% of transcripts. The combined action of the repressor (providing ~70-fold regulation) and attenuation (~10-fold) achieves tight control, ensuring minimal expression during tryptophan excess while allowing rapid derepression when levels drop.^[35] This corepressor-dependent repression mechanism exhibits evolutionary conservation across diverse bacterial taxa, reflecting its adaptive value in coordinating amino acid anabolism. Analogous systems operate in other biosynthetic pathways, such as the histidine (his) operon, which employs histidine-activated attenuation via a leader peptide with histidine codons, and the arginine (arg) operons, regulated by the ArgR repressor hexamer activated by arginine binding to operator ARG boxes. These parallels underscore a shared evolutionary strategy for nutrient-responsive gene silencing in prokaryotes, with variations in corepressor specificity and regulatory architectures tailored to metabolic demands.^[35]^[36]

Polycomb Repressive Complex

The Polycomb Repressive Complex (PRC) comprises two primary multisubunit assemblies, PRC1 and PRC2, that function cooperatively to enforce epigenetic gene silencing in eukaryotic cells, particularly during development.^[37] PRC2 consists of core subunits EZH1 or EZH2 (the catalytic SET-domain methyltransferase), EED, SUZ12, and RBBP4/7 (histone chaperones), with accessory factors forming distinct subcomplexes: PRC2.1 (incorporating PCL1/2/3 and EPOP/PAL1/2) and PRC2.2 (including JARID2 and AEBP2).^[37]^[38] PRC2 deposits the repressive histone modification trimethylation of lysine 27 on histone H3 (H3K27me3), which recruits additional silencing factors and promotes higher-order chromatin compaction to inhibit transcription.^[37] In turn, PRC1 includes RING1A or RING1B (E3 ubiquitin ligases) paired with one of six PCGF proteins (PCGF1–6), alongside either CBX family proteins (in canonical PRC1) or RYBP/YAF2 (in non-canonical PRC1).^[37]^[38] PRC1 catalyzes monoubiquitylation of histone H2A at lysine 119 (H2AK119ub1), which stabilizes H3K27me3 marks, enhances chromatin looping, and further compacts nucleosomes into transcriptionally inert structures.^[37] These complexes primarily target Hox cluster genes to sustain their repression post-embryonic induction, thereby preventing ectopic expression that could disrupt body patterning and cell differentiation.^[37] PRC2 initiates silencing by depositing H3K27me3 at promoter regions, while PRC1 reinforces this through H2AK119ub1 and chain-like chromatin interactions, forming stable Polycomb domains.^[37] The repressive marks spread bidirectionally along chromatin domains via recruitment by long non-coding RNAs (lncRNAs), such as XIST on the X chromosome or Airn and Kcnq1ot1 at imprinted loci; these lncRNAs bind variant PRC1 (PCGF3/5-containing) via adaptor proteins like hnRNPK, facilitating domain expansion and heritable silencing.^[37] Dysregulation of PRCs contributes to pathogenesis in cancer and imprinting disorders. In cancers, including lymphomas, prostate, breast, and myeloid malignancies, gain-of-function mutations in EZH2 (e.g., Y641F/N in the SET domain) hyperactivate H3K27me3, aberrantly repressing tumor suppressors like INK4A-ARF and promoting proliferation; conversely, loss-of-function alterations in EZH2 or SUZ12 (seen in ~25% of T-cell acute lymphoblastic leukemia) reduce H3K27me3, derepressing oncogenes.^[38] For imprinting disorders, heterozygous mutations in PRC2 core genes (EZH2, EED, SUZ12) impair H3K27me3 at parent-of-origin-specific loci, disrupting monoallelic silencing and causing congenital overgrowth syndromes like Weaver syndrome, where altered crosstalk with DNA methylation pathways exacerbates developmental imbalances.^[39]

Flowering Locus C

Flowering Locus C (FLC) is a MADS-box transcription factor that serves as a potent repressor of flowering in Arabidopsis thaliana, primarily by inhibiting the expression of key floral integrator genes such as FLOWERING LOCUS T (FT) and SUPPRESSOR OF OVEREXPRESSION OF CONSTANS 1 (SOC1). High levels of FLC expression delay the transition from vegetative to reproductive growth, integrating environmental cues like photoperiod and temperature to modulate flowering time. FLC achieves repression by directly binding to CArG box motifs (consensus CC[A/T]₆GG) in the regulatory regions of target genes, with chromatin immunoprecipitation studies identifying over 500 such binding sites genome-wide, predominantly in promoters and introns.^[40]^[41] In the vernalization pathway, prolonged exposure to cold temperatures (typically 4–10°C for 4–8 weeks) epigenetically silences FLC expression, thereby promoting flowering in winter-annual ecotypes. This silencing involves the induction of VIN3, a nuclear-localized protein that recruits Polycomb Repressive Complex 2 (PRC2) to deposit histone H3 lysine 27 trimethylation (H3K27me3) marks at the FLC locus, maintaining repression through mitosis even after return to warm conditions. The extent of FLC down-regulation correlates with the duration of cold exposure, with full saturation requiring 28–56 days depending on the genotype, and this response resets in progeny to ensure generation-specific vernalization requirements.^[42]^[40] FLC repression extends beyond direct target binding by interacting with other MADS-domain proteins, such as SHORT VEGETATIVE PHASE (SVP), to form heterodimers that enhance binding affinity and broaden regulatory networks. For instance, FLC-SVP complexes co-repress FT in leaves, blocking the production of systemic florigenic signals, while also impairing meristem competence by suppressing SOC1 and FD expression at the shoot apex. Mutations in FLC lead to early flowering independent of vernalization, underscoring its quantitative control over flowering time variation across natural accessions. Additionally, FLC homologs in cereals like wheat and barley contribute to vernalization responses, though with duplicated loci adapting to polyploid genomes.^[41]^[40]^[42]

References

[1]
Repressor - National Human Genome Research Institute
Repressors are proteins that turn off or reduce gene expression, which is reflected by reduced messenger RNA production from the affected gene.
[2]
Negative Transcription Regulation in Prokaryotes - Nature
Repressor proteins regulate expression by binding to a DNA sequence, called the operator, which is near the promoter of an operon, or a cluster of co-regulated ...Missing: definition | Show results with:definition
[3]
Repressor - an overview | ScienceDirect Topics
These are often controlled by a class of gene regulator proteins known as repressors that act to turn genes off. Activator proteins turn genes on. Repressor ...
[4]
Repressor - an overview | ScienceDirect Topics
Repressor is a protein that binds to DNA at an operator site and thereby prevents transcription of one or more adjacent genes. AI generated definition based on: ...<|control11|><|separator|>
[5]
Gene Expression | Learn Science at Scitable - Nature
A three-part schematic shows how a repressor protein can inhibit transcription by preventing RNA. Figure 3: Transcription repression near the promoter region.
[6]
How Genetic Switches Work - Molecular Biology of the Cell - NCBI
Some bacterial gene regulatory proteins can act as both a transcriptional activator and a repressor, depending on the precise placement of its binding sites in ...
[7]
Gene regulation | Biological Principles
... regulation, while binding sites for repressors generate negative regulation when bound. ... lacI is the gene that encodes the lac Repressor protein; CAP = ...
[8]
Regulation of Gene Expression - The CSUDH
Genes whose expression is not regulated are called constitutive genes. ... and the genes that are regulated by such repressors are called inducible genes.
[9]
Types of Gene Regulation
For example, repressors simply act ans an obstacle to block transcription. If another molecule (the inducer) interferes with the repressor, they don't bind DNA ...
[10]
[PDF] Jacob & Monod (1961) Genetic Regulatory Mechanisms
As a purely formal description, one may think of inducers as antagonists, and of co- repressors as activators, of the repressor. A variety of chemical models ...
[11]
François Jacob, Lysogeny, and the Development of the Operon Model
They proposed that a new class of genes, regulatory genes, would code for repressors that bind to operator sequences upstream of operons. The impact of the ...
[12]
Lambda repressor and gene regulation - Lasker Foundation
Mar 14, 2021 · Mark isolated the repressor in 1967. He showed that it was a ... Shortly after Gilbert and Ptashne isolated the first repressors, Gilbert ...Missing: 1966 nitrocellulose filter
[13]
The Nobel Prize in Physiology or Medicine 1965 - NobelPrize.org
The Nobel Prize in Physiology or Medicine 1965 was awarded jointly to François Jacob, André Lwoff and Jacques Monod for their discoveries concerning genetic ...
[14]
The Steroid and Thyroid Hormone Receptor Superfamily - Science
A superfamily of regulatory proteins that include receptors for thyroid hormone and the vertebrate morphogen retinoic acid.
[15]
The Nuclear Receptor Field: A Historical Overview and Future ...
Jul 26, 2018 · With time, several members of the steroid receptor family were cloned during the '80s, such as the glucocorticoid receptor [26], the estrogen ...Missing: repressors 1980s
[16]
many faces of the helix-turn-helix domain: Transcription regulation ...
The helix-turn-helix (HTH) domain is a common denominator in basal and specific transcription factors from the three super-kingdoms of life.Introduction · Structural scaffold of the HTH... · General and specific aspects...
[17]
Structures and biological functions of zinc finger proteins and their ...
Jan 9, 2022 · Zinc finger proteins are transcription factors with the finger domain, which plays a significant role in gene regulation.
[18]
Mechanisms and biotechnological applications of transcription factors
Aug 31, 2023 · Consequently, these conserved structural domains enable the ... The TetR family of transcriptional repressors. Microbiol Mol Biol Rev ...
[19]
Regulating transcription regulators via allostery and flexibility - PNAS
Dec 29, 2009 · Allosteric control of transcriptional regulatory proteins enables organisms to respond to changes in environmental and metabolic conditions.
[20]
Structural Analysis of Lac Repressor Bound to Allosteric Effectors
The lac operon is a model system for understanding how effector molecules regulate transcription and are necessary for allosteric transitions.
[21]
Repression of Transcription Initiation in Bacteria - PMC - NIH
In principle, any factor inhibiting the access of RNAP to the promoter can be considered a repressor. This definition includes not only the classical repressors ...
[22]
Operons - PMC - NIH
Operons (clusters of co-regulated genes with related functions) are a well-known feature of prokaryotic genomes.
[23]
Genetics, Inducible Operon - StatPearls - NCBI Bookshelf
Oct 17, 2022 · An inducible operon is one whose expression increases quantitatively in response to an enhancer, an inducer, or a positive regulator.
[24]
PredCRP: predicting and analysing the regulatory roles of CRP from ...
Jan 17, 2018 · Cyclic AMP receptor protein (CRP), a global regulator in Escherichia coli, regulates more than 180 genes via two roles: activation and ...
[25]
Circuitry Linking the Catabolite Repression and Csr Global ...
Cyclic AMP (cAMP) and the cAMP receptor protein (cAMP-CRP) and CsrA are the principal regulators of the catabolite repression and carbon storage global ...
[26]
A short guide to histone deacetylases including recent progress on ...
Feb 19, 2020 · The interaction between histones and DNA is important for eukaryotic gene expression. A loose interaction caused, for example, ...
[27]
Writing, erasing and reading histone lysine methylations - Nature
Apr 28, 2017 · This review summarizes enzymes responsible for histone lysine methylation and demethylation and how histone lysine methylation contributes to various ...
[28]
https://www.cell.com/neuron/fulltext/S0896-6273(01)00371-3
[29]
https://www.cell.com/cell/fulltext/S0092-8674(00)80218-4
[30]
ISOLATION OF THE LAC REPRESSOR - PNAS
ISOLATION OF THE LAC REPRESSOR. Walter Gilbert and Benno Müller-HillAuthors Info & Affiliations. December 15, 1966. 56 (6) 1891-1898.
[31]
Lac Repressor - an overview | ScienceDirect Topics
The repressor is a 155kDa tetrameric protein that binds to three operator sites within the lac operon. Isopropyl-b-d-thiogalactoside (IPTG) binds to the ...
[32]
Lac repressor-operator interaction. I. Equilibrium studies - PubMed
Lac repressor-operator interaction. I. Equilibrium studies. J Mol Biol. 1970 Feb 28;48(1):67-83. doi: 10.1016/0022-2836(70)90219-6. Authors. A D Riggs, H ...Missing: Kd et al
[33]
Isolation of the lac repressor - PubMed
Isolation of the lac repressor. Proc Natl Acad Sci U S A. 1966 Dec;56(6):1891-8. doi: 10.1073/pnas.56.6.1891. Authors. W Gilbert , B Müller-Hill. Affiliation.Missing: purification | Show results with:purification
[34]
The crystal structure of trp aporepressor at 1.8 Å shows how binding ...
Jun 18, 1987 · Binding tryptophan activates the dimer a thousandfold by moving two symmetrically-disposed flexible bihelical motifs.
[35]
trp repressor/trp operator interaction. Equilibrium and kinetic ...
The heterodimeric repressor had a 20-25-fold higher affinity for operator than did the aporepressor, and it had a 20-25-fold lower affinity for operator than ...
[36]
Evolution of bacterial trp operons and their regulation - PMC - NIH
(b) As the intracellular level of Trp rises, it binds to the TrpR aporepressor, altering its conformation. The repressor then binds at its cognate trp operators ...Missing: synergy | Show results with:synergy<|separator|>
[37]
Conservation of the binding site for the arginine repressor in all ...
Mar 22, 2001 · The arginine repressor ArgR/AhrC is a transcription factor universally conserved in bacterial genomes. Its recognition signal (the ARG box), ...<|control11|><|separator|>
[38]
The molecular principles of gene regulation by Polycomb repressive ...
This work has shown that Polycomb complexes comprise catalytic cores, which bind auxiliary proteins to create distinct PRC1 and PRC2 assemblies. In this section ...
[39]
Mechanisms of Polycomb group protein function in cancer - Nature
Jan 19, 2022 · PcG proteins form two main epigenetic complexes, the Polycomb Repressive Complex 1 and 2 (PRC1 and PRC2), which were later identified as ...
[40]
PRC2 functions in development and congenital disorders - PMC
Oct 1, 2019 · Polycomb repressive complex 2 (PRC2) is a conserved chromatin regulator that is responsible for the methylation of histone H3 lysine 27 (H3K27).
[41]
FLOWERING LOCUS C (FLC) regulates development pathways ...
FLC has a key role in the timing of the initiation of flowering in Arabidopsis. FLC binds and represses two genes that promote flowering, FT and SOC1.
[42]
The transcription factor FLC confers a flowering response to ...
The transcription factor FLC confers a flowering response to vernalization by repressing meristem competence and systemic signaling in Arabidopsis · Abstract.
[43]
The central role of FLOWERING LOCUS C (FLC) - PNAS
In this paper, we demonstrate that the FLC gene is involved directly in controlling the response to vernalization and more generally in the timing of the ...