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Wikipedia

Transcription factor

February 16, 2024

In molecular biology, a transcription factor (TF) (or sequence-specific DNA-binding factor) is a protein that controls the rate of transcription of genetic information from DNA to messenger RNA, by binding to a specific DNA sequence.[1][2] The function of TFs is to regulate—turn on and off—genes in order to make sure that they are expressed in the desired cells at the right time and in the right amount throughout the life of the cell and the organism. Groups of TFs function in a coordinated fashion to direct cell division, cell growth, and cell death throughout life; cell migration and organization (body plan) during embryonic development; and intermittently in response to signals from outside the cell, such as a hormone. There are 1500-1600 TFs in the human genome.[3][4] Transcription factors are members of the proteome as well as regulome.

Transcription factor glossary
  • gene expression – the process by which information from a gene is used in the synthesis of a functional gene product such as a protein
  • transcription – the process of making messenger RNA (mRNA) from a DNA template by RNA polymerase
  • transcription factor – a protein that binds to DNA and regulates gene expression by promoting or suppressing transcription
  • transcriptional regulationcontrolling the rate of gene transcription for example by helping or hindering RNA polymerase binding to DNA
  • upregulation, activation, or promotionincrease the rate of gene transcription
  • downregulation, repression, or suppressiondecrease the rate of gene transcription
  • coactivator – a protein (or a small molecule) that works with transcription factors to increase the rate of gene transcription
  • corepressor – a protein (or a small molecule) that works with transcription factors to decrease the rate of gene transcription
  • response element – a specific sequence of DNA that a transcription factor binds to
Illustration of an activator

TFs work alone or with other proteins in a complex, by promoting (as an activator), or blocking (as a repressor) the recruitment of RNA polymerase (the enzyme that performs the transcription of genetic information from DNA to RNA) to specific genes.[5][6][7]

A defining feature of TFs is that they contain at least one DNA-binding domain (DBD), which attaches to a specific sequence of DNA adjacent to the genes that they regulate.[8][9] TFs are grouped into classes based on their DBDs.[10][11] Other proteins such as coactivators, chromatin remodelers, histone acetyltransferases, histone deacetylases, kinases, and methylases are also essential to gene regulation, but lack DNA-binding domains, and therefore are not TFs.[12]

TFs are of interest in medicine because TF mutations can cause specific diseases, and medications can be potentially targeted toward them.

Number edit

Main listing: List of human transcription factors

Transcription factors are essential for the regulation of gene expression and are, as a consequence, found in all living organisms. The number of transcription factors found within an organism increases with genome size, and larger genomes tend to have more transcription factors per gene.[13]

There are approximately 2800 proteins in the human genome that contain DNA-binding domains, and 1600 of these are presumed to function as transcription factors,[3] though other studies indicate it to be a smaller number.[14] Therefore, approximately 10% of genes in the genome code for transcription factors, which makes this family the single largest family of human proteins. Furthermore, genes are often flanked by several binding sites for distinct transcription factors, and efficient expression of each of these genes requires the cooperative action of several different transcription factors (see, for example, hepatocyte nuclear factors). Hence, the combinatorial use of a subset of the approximately 2000 human transcription factors easily accounts for the unique regulation of each gene in the human genome during development.[12]

Mechanism edit

Transcription factors bind to either enhancer or promoter regions of DNA adjacent to the genes that they regulate. Depending on the transcription factor, the transcription of the adjacent gene is either up- or down-regulated. Transcription factors use a variety of mechanisms for the regulation of gene expression.[15] These mechanisms include:

  • stabilize or block the binding of RNA polymerase to DNA
  • catalyze the acetylation or deacetylation of histone proteins. The transcription factor can either do this directly or recruit other proteins with this catalytic activity. Many transcription factors use one or the other of two opposing mechanisms to regulate transcription:[16]
    • histone acetyltransferase (HAT) activity – acetylates histone proteins, which weakens the association of DNA with histones, which make the DNA more accessible to transcription, thereby up-regulating transcription
    • histone deacetylase (HDAC) activity – deacetylates histone proteins, which strengthens the association of DNA with histones, which make the DNA less accessible to transcription, thereby down-regulating transcription
  • recruit coactivator or corepressor proteins to the transcription factor DNA complex[17]

Function edit

Transcription factors are one of the groups of proteins that read and interpret the genetic "blueprint" in the DNA. They bind to the DNA and help initiate a program of increased or decreased gene transcription. As such, they are vital for many important cellular processes. Below are some of the important functions and biological roles transcription factors are involved in:

Basal transcriptional regulation edit

In eukaryotes, an important class of transcription factors called general transcription factors (GTFs) are necessary for transcription to occur.[18][19][20] Many of these GTFs do not actually bind DNA, but rather are part of the large transcription preinitiation complex that interacts with RNA polymerase directly. The most common GTFs are TFIIA, TFIIB, TFIID (see also TATA binding protein), TFIIE, TFIIF, and TFIIH.[21] The preinitiation complex binds to promoter regions of DNA upstream to the gene that they regulate.

Differential enhancement of transcription edit

Other transcription factors differentially regulate the expression of various genes by binding to enhancer regions of DNA adjacent to regulated genes. These transcription factors are critical to making sure that genes are expressed in the right cell at the right time and in the right amount, depending on the changing requirements of the organism.

Development edit

Many transcription factors in multicellular organisms are involved in development.[22] Responding to stimuli, these transcription factors turn on/off the transcription of the appropriate genes, which, in turn, allows for changes in cell morphology or activities needed for cell fate determination and cellular differentiation. The Hox transcription factor family, for example, is important for proper body pattern formation in organisms as diverse as fruit flies to humans.[23][24] Another example is the transcription factor encoded by the sex-determining region Y (SRY) gene, which plays a major role in determining sex in humans.[25]

Response to intercellular signals edit

Cells can communicate with each other by releasing molecules that produce signaling cascades within another receptive cell. If the signal requires upregulation or downregulation of genes in the recipient cell, often transcription factors will be downstream in the signaling cascade.[26] Estrogen signaling is an example of a fairly short signaling cascade that involves the estrogen receptor transcription factor: Estrogen is secreted by tissues such as the ovaries and placenta, crosses the cell membrane of the recipient cell, and is bound by the estrogen receptor in the cell's cytoplasm. The estrogen receptor then goes to the cell's nucleus and binds to its DNA-binding sites, changing the transcriptional regulation of the associated genes.[27]

Response to environment edit

Not only do transcription factors act downstream of signaling cascades related to biological stimuli but they can also be downstream of signaling cascades involved in environmental stimuli. Examples include heat shock factor (HSF), which upregulates genes necessary for survival at higher temperatures,[28] hypoxia inducible factor (HIF), which upregulates genes necessary for cell survival in low-oxygen environments,[29] and sterol regulatory element binding protein (SREBP), which helps maintain proper lipid levels in the cell.[30]

Cell cycle control edit

Many transcription factors, especially some that are proto-oncogenes or tumor suppressors, help regulate the cell cycle and as such determine how large a cell will get and when it can divide into two daughter cells.[31][32] One example is the Myc oncogene, which has important roles in cell growth and apoptosis.[33]

Pathogenesis edit

Transcription factors can also be used to alter gene expression in a host cell to promote pathogenesis. A well studied example of this are the transcription-activator like effectors (TAL effectors) secreted by Xanthomonas bacteria. When injected into plants, these proteins can enter the nucleus of the plant cell, bind plant promoter sequences, and activate transcription of plant genes that aid in bacterial infection.[34] TAL effectors contain a central repeat region in which there is a simple relationship between the identity of two critical residues in sequential repeats and sequential DNA bases in the TAL effector's target site.[35][36] This property likely makes it easier for these proteins to evolve in order to better compete with the defense mechanisms of the host cell.[37]

Regulation edit

It is common in biology for important processes to have multiple layers of regulation and control. This is also true with transcription factors: Not only do transcription factors control the rates of transcription to regulate the amounts of gene products (RNA and protein) available to the cell but transcription factors themselves are regulated (often by other transcription factors). Below is a brief synopsis of some of the ways that the activity of transcription factors can be regulated:

Synthesis edit

Transcription factors (like all proteins) are transcribed from a gene on a chromosome into RNA, and then the RNA is translated into protein. Any of these steps can be regulated to affect the production (and thus activity) of a transcription factor. An implication of this is that transcription factors can regulate themselves. For example, in a negative feedback loop, the transcription factor acts as its own repressor: If the transcription factor protein binds the DNA of its own gene, it down-regulates the production of more of itself. This is one mechanism to maintain low levels of a transcription factor in a cell.[38]

Nuclear localization edit

In eukaryotes, transcription factors (like most proteins) are transcribed in the nucleus but are then translated in the cell's cytoplasm. Many proteins that are active in the nucleus contain nuclear localization signals that direct them to the nucleus. But, for many transcription factors, this is a key point in their regulation.[39] Important classes of transcription factors such as some nuclear receptors must first bind a ligand while in the cytoplasm before they can relocate to the nucleus.[39]

Activation edit

Transcription factors may be activated (or deactivated) through their signal-sensing domain by a number of mechanisms including:

  • ligand binding – Not only is ligand binding able to influence where a transcription factor is located within a cell but ligand binding can also affect whether the transcription factor is in an active state and capable of binding DNA or other cofactors (see, for example, nuclear receptors).
  • phosphorylation[40][41] – Many transcription factors such as STAT proteins must be phosphorylated before they can bind DNA.
  • interaction with other transcription factors (e.g., homo- or hetero-dimerization) or coregulatory proteins

Accessibility of DNA-binding site edit

In eukaryotes, DNA is organized with the help of histones into compact particles called nucleosomes, where sequences of about 147 DNA base pairs make ~1.65 turns around histone protein octamers. DNA within nucleosomes is inaccessible to many transcription factors. Some transcription factors, so-called pioneer factors are still able to bind their DNA binding sites on the nucleosomal DNA. For most other transcription factors, the nucleosome should be actively unwound by molecular motors such as chromatin remodelers.[42] Alternatively, the nucleosome can be partially unwrapped by thermal fluctuations, allowing temporary access to the transcription factor binding site. In many cases, a transcription factor needs to compete for binding to its DNA binding site with other transcription factors and histones or non-histone chromatin proteins.[43] Pairs of transcription factors and other proteins can play antagonistic roles (activator versus repressor) in the regulation of the same gene.

Availability of other cofactors/transcription factors edit

Most transcription factors do not work alone. Many large TF families form complex homotypic or heterotypic interactions through dimerization.[44] For gene transcription to occur, a number of transcription factors must bind to DNA regulatory sequences. This collection of transcription factors, in turn, recruit intermediary proteins such as cofactors that allow efficient recruitment of the preinitiation complex and RNA polymerase. Thus, for a single transcription factor to initiate transcription, all of these other proteins must also be present, and the transcription factor must be in a state where it can bind to them if necessary. Cofactors are proteins that modulate the effects of transcription factors. Cofactors are interchangeable between specific gene promoters; the protein complex that occupies the promoter DNA and the amino acid sequence of the cofactor determine its spatial conformation. For example, certain steroid receptors can exchange cofactors with NF-κB, which is a switch between inflammation and cellular differentiation; thereby steroids can affect the inflammatory response and function of certain tissues.[45]

Interaction with methylated cytosine edit

Transcription factors and methylated cytosines in DNA both have major roles in regulating gene expression. (Methylation of cytosine in DNA primarily occurs where cytosine is followed by guanine in the 5' to 3' DNA sequence, a CpG site.) Methylation of CpG sites in a promoter region of a gene usually represses gene transcription,[46] while methylation of CpGs in the body of a gene increases expression.[47] TET enzymes play a central role in demethylation of methylated cytosines. Demethylation of CpGs in a gene promoter by TET enzyme activity increases transcription of the gene.[48]

The DNA binding sites of 519 transcription factors were evaluated.[49] Of these, 169 transcription factors (33%) did not have CpG dinucleotides in their binding sites, and 33 transcription factors (6%) could bind to a CpG-containing motif but did not display a preference for a binding site with either a methylated or unmethylated CpG. There were 117 transcription factors (23%) that were inhibited from binding to their binding sequence if it contained a methylated CpG site, 175 transcription factors (34%) that had enhanced binding if their binding sequence had a methylated CpG site, and 25 transcription factors (5%) were either inhibited or had enhanced binding depending on where in the binding sequence the methylated CpG was located.

TET enzymes do not specifically bind to methylcytosine except when recruited (see DNA demethylation). Multiple transcription factors important in cell differentiation and lineage specification, including NANOG, SALL4A, WT1, EBF1, PU.1, and E2A, have been shown to recruit TET enzymes to specific genomic loci (primarily enhancers) to act on methylcytosine (mC) and convert it to hydroxymethylcytosine hmC (and in most cases marking them for subsequent complete demethylation to cytosine).[50] TET-mediated conversion of mC to hmC appears to disrupt the binding of 5mC-binding proteins including MECP2 and MBD (Methyl-CpG-binding domain) proteins, facilitating nucleosome remodeling and the binding of transcription factors, thereby activating transcription of those genes. EGR1 is an important transcription factor in memory formation. It has an essential role in brain neuron epigenetic reprogramming. The transcription factor EGR1 recruits the TET1 protein that initiates a pathway of DNA demethylation.[51] EGR1, together with TET1, is employed in programming the distribution of methylation sites on brain DNA during brain development and in learning (see Epigenetics in learning and memory).

Structure edit

 
Schematic diagram of the amino acid sequence (amino terminus to the left and carboxylic acid terminus to the right) of a prototypical transcription factor that contains (1) a DNA-binding domain (DBD), (2) signal-sensing domain (SSD), and Activation domain (AD). The order of placement and the number of domains may differ in various types of transcription factors. In addition, the transactivation and signal-sensing functions are frequently contained within the same domain.
 
Domain architecture example: Lactose Repressor (LacI). The N-terminal DNA binding domain (labeled) of the lac repressor binds its target DNA sequence (gold) in the major groove using a helix-turn-helix motif. Effector molecule binding (green) occurs in the regulatory domain (labeled). This triggers an allosteric response mediated by the linker region (labeled).

Transcription factors are modular in structure and contain the following domains:[1]

  • DNA-binding domain (DBD), which attaches to specific sequences of DNA (enhancer or promoter. Necessary component for all vectors. Used to drive transcription of the vector's transgene promoter sequences) adjacent to regulated genes. DNA sequences that bind transcription factors are often referred to as response elements.
  • Activation domain (AD), which contains binding sites for other proteins such as transcription coregulators. These binding sites are frequently referred to as activation functions (AFs), Transactivation domain (TAD) or Trans-activating domain TAD, not to be confused with topologically associating domain (TAD).[52]
  • An optional signal-sensing domain (SSD) (e.g., a ligand-binding domain), which senses external signals and, in response, transmits these signals to the rest of the transcription complex, resulting in up- or down-regulation of gene expression. Also, the DBD and signal-sensing domains may reside on separate proteins that associate within the transcription complex to regulate gene expression.

DNA-binding domain edit

 
DNA contacts of different types of DNA-binding domains of transcription factors
Main article: DNA-binding domain

The portion (domain) of the transcription factor that binds DNA is called its DNA-binding domain. Below is a partial list of some of the major families of DNA-binding domains/transcription factors:

Family InterPro Pfam SCOP
basic helix-loop-helix[53] InterProIPR001092 Pfam PF00010 SCOP 47460
basic-leucine zipper (bZIP)[54] InterProIPR004827 Pfam PF00170 SCOP 57959
C-terminal effector domain of the bipartite response regulators InterProIPR001789 Pfam PF00072 SCOP 46894
AP2/ERF/GCC box InterProIPR001471 Pfam PF00847 SCOP 54176
helix-turn-helix[55]
homeodomain proteins, which are encoded by homeobox genes, are transcription factors. Homeodomain proteins play critical roles in the regulation of development.[56][57] InterProIPR009057 Pfam PF00046 SCOP 46689
lambda repressor-like InterProIPR010982 SCOP 47413
srf-like (serum response factor) InterProIPR002100 Pfam PF00319 SCOP 55455
paired box[58]
winged helix InterProIPR013196 Pfam PF08279 SCOP 46785
zinc fingers[59]
* multi-domain Cys2His2 zinc fingers[60] InterProIPR007087 Pfam PF00096 SCOP 57667
* Zn2/Cys6 SCOP 57701
* Zn2/Cys8 nuclear receptor zinc finger InterProIPR001628 Pfam PF00105 SCOP 57716

Response elements edit

The DNA sequence that a transcription factor binds to is called a transcription factor-binding site or response element.[61]

Transcription factors interact with their binding sites using a combination of electrostatic (of which hydrogen bonds are a special case) and Van der Waals forces. Due to the nature of these chemical interactions, most transcription factors bind DNA in a sequence specific manner. However, not all bases in the transcription factor-binding site may actually interact with the transcription factor. In addition, some of these interactions may be weaker than others. Thus, transcription factors do not bind just one sequence but are capable of binding a subset of closely related sequences, each with a different strength of interaction.

For example, although the consensus binding site for the TATA-binding protein (TBP) is TATAAAA, the TBP transcription factor can also bind similar sequences such as TATATAT or TATATAA.

Because transcription factors can bind a set of related sequences and these sequences tend to be short, potential transcription factor binding sites can occur by chance if the DNA sequence is long enough. It is unlikely, however, that a transcription factor will bind all compatible sequences in the genome of the cell. Other constraints, such as DNA accessibility in the cell or availability of cofactors may also help dictate where a transcription factor will actually bind. Thus, given the genome sequence, it is still difficult to predict where a transcription factor will actually bind in a living cell.

Additional recognition specificity, however, may be obtained through the use of more than one DNA-binding domain (for example tandem DBDs in the same transcription factor or through dimerization of two transcription factors) that bind to two or more adjacent sequences of DNA.

Clinical significance edit

Transcription factors are of clinical significance for at least two reasons: (1) mutations can be associated with specific diseases, and (2) they can be targets of medications.

Disorders edit

Due to their important roles in development, intercellular signaling, and cell cycle, some human diseases have been associated with mutations in transcription factors.[62]

Many transcription factors are either tumor suppressors or oncogenes, and, thus, mutations or aberrant regulation of them is associated with cancer. Three groups of transcription factors are known to be important in human cancer: (1) the NF-kappaB and AP-1 families, (2) the STAT family and (3) the steroid receptors.[63]

Below are a few of the better-studied examples:

Condition Description Locus
Rett syndrome Mutations in the MECP2 transcription factor are associated with Rett syndrome, a neurodevelopmental disorder.[64][65] Xq28
Diabetes A rare form of diabetes called MODY (Maturity onset diabetes of the young) can be caused by mutations in hepatocyte nuclear factors (HNFs)[66] or insulin promoter factor-1 (IPF1/Pdx1).[67] multiple
Developmental verbal dyspraxia Mutations in the FOXP2 transcription factor are associated with developmental verbal dyspraxia, a disease in which individuals are unable to produce the finely coordinated movements required for speech.[68] 7q31
Autoimmune diseases Mutations in the FOXP3 transcription factor cause a rare form of autoimmune disease called IPEX.[69] Xp11.23-q13.3
Li-Fraumeni syndrome Caused by mutations in the tumor suppressor p53.[70] 17p13.1
Breast cancer The STAT family is relevant to breast cancer.[71] multiple
Multiple cancers The HOX family are involved in a variety of cancers.[72] multiple
Osteoarthritis Mutation or reduced activity of SOX9[73]

Potential drug targets edit

See also: Therapeutic gene modulation

Approximately 10% of currently prescribed drugs directly target the nuclear receptor class of transcription factors.[74] Examples include tamoxifen and bicalutamide for the treatment of breast and prostate cancer, respectively, and various types of anti-inflammatory and anabolic steroids.[75] In addition, transcription factors are often indirectly modulated by drugs through signaling cascades. It might be possible to directly target other less-explored transcription factors such as NF-κB with drugs.[76][77][78][79] Transcription factors outside the nuclear receptor family are thought to be more difficult to target with small molecule therapeutics since it is not clear that they are "drugable" but progress has been made on Pax2[80][81] and the notch pathway.[82]

Role in evolution edit

Further information: Evolutionary developmental biology

Gene duplications have played a crucial role in the evolution of species. This applies particularly to transcription factors. Once they occur as duplicates, accumulated mutations encoding for one copy can take place without negatively affecting the regulation of downstream targets. However, changes of the DNA binding specificities of the single-copy Leafy transcription factor, which occurs in most land plants, have recently been elucidated. In that respect, a single-copy transcription factor can undergo a change of specificity through a promiscuous intermediate without losing function. Similar mechanisms have been proposed in the context of all alternative phylogenetic hypotheses, and the role of transcription factors in the evolution of all species.[83][84]

Role in biocontrol activity edit

The transcription factors have a role in resistance activity which is important for successful biocontrol activity. The resistant to oxidative stress and alkaline pH sensing were contributed from the transcription factor Yap1 and Rim101 of the Papiliotrema terrestris LS28 as molecular tools revealed an understanding of the genetic mechanisms underlying the biocontrol activity which supports disease management programs based on biological and integrated control.[85]

Analysis edit

There are different technologies available to analyze transcription factors. On the genomic level, DNA-sequencing[86] and database research are commonly used.[87] The protein version of the transcription factor is detectable by using specific antibodies. The sample is detected on a western blot. By using electrophoretic mobility shift assay (EMSA),[88] the activation profile of transcription factors can be detected. A multiplex approach for activation profiling is a TF chip system where several different transcription factors can be detected in parallel.

The most commonly used method for identifying transcription factor binding sites is chromatin immunoprecipitation (ChIP).[89] This technique relies on chemical fixation of chromatin with formaldehyde, followed by co-precipitation of DNA and the transcription factor of interest using an antibody that specifically targets that protein. The DNA sequences can then be identified by microarray or high-throughput sequencing (ChIP-seq) to determine transcription factor binding sites. If no antibody is available for the protein of interest, DamID may be a convenient alternative.[90]

Classes edit

As described in more detail below, transcription factors may be classified by their (1) mechanism of action, (2) regulatory function, or (3) sequence homology (and hence structural similarity) in their DNA-binding domains.

Mechanistic edit

There are two mechanistic classes of transcription factors:

  • General transcription factors are involved in the formation of a preinitiation complex. The most common are abbreviated as TFIIA, TFIIB, TFIID, TFIIE, TFIIF, and TFIIH. They are ubiquitous and interact with the core promoter region surrounding the transcription start site(s) of all class II genes.[91]
  • Upstream transcription factors are proteins that bind somewhere upstream of the initiation site to stimulate or repress transcription. These are roughly synonymous with specific transcription factors, because they vary considerably depending on what recognition sequences are present in the proximity of the gene.[92]
Examples of specific transcription factors[92]
Factor Structural type Recognition sequence Binds as
SP1 Zinc finger 5'-GGGCGG-3' Monomer
AP-1 Basic zipper 5'-TGA(G/C)TCA-3' Dimer
C/EBP Basic zipper 5'-ATTGCGCAAT-3' Dimer
Heat shock factor Basic zipper 5'-XGAAX-3' Trimer
ATF/CREB Basic zipper 5'-TGACGTCA-3' Dimer
c-Myc Basic helix-loop-helix 5'-CACGTG-3' Dimer
Oct-1 Helix-turn-helix 5'-ATGCAAAT-3' Monomer
NF-1 Novel 5'-TTGGCXXXXXGCCAA-3' Dimer
(G/C) = G or C
X = A, T, G or C

Functional edit

Transcription factors have been classified according to their regulatory function:[12]

  • I. constitutively active – present in all cells at all times – general transcription factors, Sp1, NF1, CCAAT
  • II. conditionally active – requires activation
    • II.A developmental (cell specific) – expression is tightly controlled, but, once expressed, require no additional activation – GATA, HNF, PIT-1, MyoD, Myf5, Hox, Winged Helix
    • II.B signal-dependent – requires external signal for activation
      • II.B.1 extracellular ligand (endocrine or paracrine)-dependentnuclear receptors
      • II.B.2 intracellular ligand (autocrine)-dependent – activated by small intracellular molecules – SREBP, p53, orphan nuclear receptors
      • II.B.3 cell membrane receptor-dependent – second messenger signaling cascades resulting in the phosphorylation of the transcription factor
        • II.B.3.a resident nuclear factors – reside in the nucleus regardless of activation state – CREB, AP-1, Mef2
        • II.B.3.b latent cytoplasmic factors – inactive form reside in the cytoplasm, but, when activated, are translocated into the nucleus – STAT, R-SMAD, NF-κB, Notch, TUBBY, NFAT

Structural edit

Transcription factors are often classified based on the sequence similarity and hence the tertiary structure of their DNA-binding domains:[93][11][94][10]

  • 1 Superclass: Basic Domains
    • 1.1 Class: Leucine zipper factors (bZIP)
      • 1.1.1 Family: AP-1(-like) components; includes (c-Fos/c-Jun)
      • 1.1.2 Family: CREB
      • 1.1.3 Family: C/EBP-like factors
      • 1.1.4 Family: bZIP / PAR
      • 1.1.5 Family: Plant G-box binding factors
      • 1.1.6 Family: ZIP only
    • 1.2 Class: Helix-loop-helix factors (bHLH)
      • 1.2.1 Family: Ubiquitous (class A) factors
      • 1.2.2 Family: Myogenic transcription factors (MyoD)
      • 1.2.3 Family: Achaete-Scute
      • 1.2.4 Family: Tal/Twist/Atonal/Hen
    • 1.3 Class: Helix-loop-helix / leucine zipper factors (bHLH-ZIP)
      • 1.3.1 Family: Ubiquitous bHLH-ZIP factors; includes USF (USF1, USF2); SREBP (SREBP)
      • 1.3.2 Family: Cell-cycle controlling factors; includes c-Myc
    • 1.4 Class: NF-1
      • 1.4.1 Family: NF-1 (A, B, C, X)
    • 1.5 Class: RF-X
    • 1.6 Class: bHSH
  • 2 Superclass: Zinc-coordinating DNA-binding domains
    • 2.1 Class: Cys4 zinc finger of nuclear receptor type
    • 2.2 Class: diverse Cys4 zinc fingers
    • 2.3 Class: Cys2His2 zinc finger domain
      • 2.3.1 Family: Ubiquitous factors, includes TFIIIA, Sp1
      • 2.3.2 Family: Developmental / cell cycle regulators; includes Krüppel
      • 2.3.4 Family: Large factors with NF-6B-like binding properties
    • 2.4 Class: Cys6 cysteine-zinc cluster
    • 2.5 Class: Zinc fingers of alternating composition
  • 3 Superclass: Helix-turn-helix
    • 3.1 Class: Homeo domain
      • 3.1.1 Family: Homeo domain only; includes Ubx
      • 3.1.2 Family: POU domain factors; includes Oct
      • 3.1.3 Family: Homeo domain with LIM region
      • 3.1.4 Family: homeo domain plus zinc finger motifs
    • 3.2 Class: Paired box
      • 3.2.1 Family: Paired plus homeo domain
      • 3.2.2 Family: Paired domain only
    • 3.3 Class: Fork head / winged helix
      • 3.3.1 Family: Developmental regulators; includes forkhead
      • 3.3.2 Family: Tissue-specific regulators
      • 3.3.3 Family: Cell-cycle controlling factors
      • 3.3.0 Family: Other regulators
    • 3.4 Class: Heat Shock Factors
      • 3.4.1 Family: HSF
    • 3.5 Class: Tryptophan clusters
    • 3.6 Class: TEA ( transcriptional enhancer factor) domain
  • 4 Superclass: beta-Scaffold Factors with Minor Groove Contacts
    • 4.1 Class: RHR (Rel homology region)
    • 4.2 Class: STAT
    • 4.3 Class: p53
      • 4.3.1 Family: p53
    • 4.4 Class: MADS box
      • 4.4.1 Family: Regulators of differentiation; includes (Mef2)
      • 4.4.2 Family: Responders to external signals, SRF (serum response factor) (SRF)
      • 4.4.3 Family: Metabolic regulators (ARG80)
    • 4.5 Class: beta-Barrel alpha-helix transcription factors
    • 4.6 Class: TATA binding proteins
      • 4.6.1 Family: TBP
    • 4.7 Class: HMG-box
      • 4.7.1 Family: SOX genes, SRY
      • 4.7.2 Family: TCF-1 (TCF1)
      • 4.7.3 Family: HMG2-related, SSRP1
      • 4.7.4 Family: UBF
      • 4.7.5 Family: MATA
    • 4.8 Class: Heteromeric CCAAT factors
      • 4.8.1 Family: Heteromeric CCAAT factors
    • 4.9 Class: Grainyhead
      • 4.9.1 Family: Grainyhead
    • 4.10 Class: Cold-shock domain factors
      • 4.10.1 Family: csd
    • 4.11 Class: Runt
      • 4.11.1 Family: Runt
  • 0 Superclass: Other Transcription Factors
    • 0.1 Class: Copper fist proteins
    • 0.2 Class: HMGI(Y) (HMGA1)
      • 0.2.1 Family: HMGI(Y)
    • 0.3 Class: Pocket domain
    • 0.4 Class: E1A-like factors
    • 0.5 Class: AP2/EREBP-related factors
      • 0.5.1 Family: AP2
      • 0.5.2 Family: EREBP
      • 0.5.3 Superfamily: AP2/B3
        • 0.5.3.1 Family: ARF
        • 0.5.3.2 Family: ABI
        • 0.5.3.3 Family: RAV

Transcription factor databases edit

There are numerous databases cataloging information about transcription factors, but their scope and utility vary dramatically. Some may contain only information about the actual proteins, some about their binding sites, or about their target genes. Examples include the following:

  • footprintDB-- a metadatabase of multiple databases, including JASPAR and others
  • JASPAR: database of transcription factor binding sites for eukaryotes
  • PlantTFD: Plant transcription factor database[95]
  • TcoF-DB: Database of transcription co-factors and transcription factor interactions[96]
  • TFcheckpoint: database of human, mouse and rat TF candidates
  • transcriptionfactor.org (now commercial, selling reagents)
  • MethMotif.org: An integrative cell-specific database of transcription factor binding motifs coupled with DNA methylation profiles. [97]

See also edit

References edit

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Further reading edit

  • Carretero-Paulet, Lorenzo; Galstyan, Anahit; Roig-Villanova, Irma; Martínez-García, Jaime F.; Bilbao-Castro, Jose R. «Genome-Wide Classification and Evolutionary Analysis of the bHLH Family of Transcription Factors in Arabidopsis, Poplar, Rice, Moss, and Algae». Plant Physiology, 153, 3, 2010-07, pàg. 1398–1412. doi:10.1104/pp.110.153593. ISSN 0032-0889
  • Jin J, He K, Tang X, Li Z, Lv L, Zhao Y, Luo J, Gao G (2015). "An Arabidopsis Transcriptional Regulatory Map Reveals Distinct Functional and Evolutionary Features of Novel Transcription Factors". Molecular Biology and Evolution. 32 (7): 1767–73. doi:10.1093/molbev/msv058. PMC 4476157. PMID 25750178.
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February 16, 2024
transcription, factor, molecular, biology, transcription, factor, sequence, specific, binding, factor, protein, that, controls, rate, transcription, genetic, information, from, messenger, binding, specific, sequence, function, regulate, turn, genes, order, mak. In molecular biology a transcription factor TF or sequence specific DNA binding factor is a protein that controls the rate of transcription of genetic information from DNA to messenger RNA by binding to a specific DNA sequence 1 2 The function of TFs is to regulate turn on and off genes in order to make sure that they are expressed in the desired cells at the right time and in the right amount throughout the life of the cell and the organism Groups of TFs function in a coordinated fashion to direct cell division cell growth and cell death throughout life cell migration and organization body plan during embryonic development and intermittently in response to signals from outside the cell such as a hormone There are 1500 1600 TFs in the human genome 3 4 Transcription factors are members of the proteome as well as regulome Transcription factor glossarygene expression the process by which information from a gene is used in the synthesis of a functional gene product such as a protein transcription the process of making messenger RNA mRNA from a DNA template by RNA polymerase transcription factor a protein that binds to DNA and regulates gene expression by promoting or suppressing transcription transcriptional regulation controlling the rate of gene transcription for example by helping or hindering RNA polymerase binding to DNA upregulation activation or promotion increase the rate of gene transcription downregulation repression or suppression decrease the rate of gene transcription coactivator a protein or a small molecule that works with transcription factors to increase the rate of gene transcription corepressor a protein or a small molecule that works with transcription factors to decrease the rate of gene transcription response element a specific sequence of DNA that a transcription factor binds tovteIllustration of an activatorTFs work alone or with other proteins in a complex by promoting as an activator or blocking as a repressor the recruitment of RNA polymerase the enzyme that performs the transcription of genetic information from DNA to RNA to specific genes 5 6 7 A defining feature of TFs is that they contain at least one DNA binding domain DBD which attaches to a specific sequence of DNA adjacent to the genes that they regulate 8 9 TFs are grouped into classes based on their DBDs 10 11 Other proteins such as coactivators chromatin remodelers histone acetyltransferases histone deacetylases kinases and methylases are also essential to gene regulation but lack DNA binding domains and therefore are not TFs 12 TFs are of interest in medicine because TF mutations can cause specific diseases and medications can be potentially targeted toward them Contents 1 Number 2 Mechanism 3 Function 3 1 Basal transcriptional regulation 3 2 Differential enhancement of transcription 3 2 1 Development 3 2 2 Response to intercellular signals 3 2 3 Response to environment 3 2 4 Cell cycle control 3 2 5 Pathogenesis 4 Regulation 4 1 Synthesis 4 2 Nuclear localization 4 3 Activation 4 4 Accessibility of DNA binding site 4 5 Availability of other cofactors transcription factors 4 6 Interaction with methylated cytosine 5 Structure 5 1 DNA binding domain 5 2 Response elements 6 Clinical significance 6 1 Disorders 6 2 Potential drug targets 7 Role in evolution 8 Role in biocontrol activity 9 Analysis 10 Classes 10 1 Mechanistic 10 2 Functional 10 3 Structural 11 Transcription factor databases 12 See also 13 References 14 Further reading 15 External linksNumber editMain listing List of human transcription factors Transcription factors are essential for the regulation of gene expression and are as a consequence found in all living organisms The number of transcription factors found within an organism increases with genome size and larger genomes tend to have more transcription factors per gene 13 There are approximately 2800 proteins in the human genome that contain DNA binding domains and 1600 of these are presumed to function as transcription factors 3 though other studies indicate it to be a smaller number 14 Therefore approximately 10 of genes in the genome code for transcription factors which makes this family the single largest family of human proteins Furthermore genes are often flanked by several binding sites for distinct transcription factors and efficient expression of each of these genes requires the cooperative action of several different transcription factors see for example hepatocyte nuclear factors Hence the combinatorial use of a subset of the approximately 2000 human transcription factors easily accounts for the unique regulation of each gene in the human genome during development 12 Mechanism editTranscription factors bind to either enhancer or promoter regions of DNA adjacent to the genes that they regulate Depending on the transcription factor the transcription of the adjacent gene is either up or down regulated Transcription factors use a variety of mechanisms for the regulation of gene expression 15 These mechanisms include stabilize or block the binding of RNA polymerase to DNA catalyze the acetylation or deacetylation of histone proteins The transcription factor can either do this directly or recruit other proteins with this catalytic activity Many transcription factors use one or the other of two opposing mechanisms to regulate transcription 16 histone acetyltransferase HAT activity acetylates histone proteins which weakens the association of DNA with histones which make the DNA more accessible to transcription thereby up regulating transcription histone deacetylase HDAC activity deacetylates histone proteins which strengthens the association of DNA with histones which make the DNA less accessible to transcription thereby down regulating transcription recruit coactivator or corepressor proteins to the transcription factor DNA complex 17 Function editTranscription factors are one of the groups of proteins that read and interpret the genetic blueprint in the DNA They bind to the DNA and help initiate a program of increased or decreased gene transcription As such they are vital for many important cellular processes Below are some of the important functions and biological roles transcription factors are involved in Basal transcriptional regulation edit In eukaryotes an important class of transcription factors called general transcription factors GTFs are necessary for transcription to occur 18 19 20 Many of these GTFs do not actually bind DNA but rather are part of the large transcription preinitiation complex that interacts with RNA polymerase directly The most common GTFs are TFIIA TFIIB TFIID see also TATA binding protein TFIIE TFIIF and TFIIH 21 The preinitiation complex binds to promoter regions of DNA upstream to the gene that they regulate Differential enhancement of transcription edit Other transcription factors differentially regulate the expression of various genes by binding to enhancer regions of DNA adjacent to regulated genes These transcription factors are critical to making sure that genes are expressed in the right cell at the right time and in the right amount depending on the changing requirements of the organism Development edit Many transcription factors in multicellular organisms are involved in development 22 Responding to stimuli these transcription factors turn on off the transcription of the appropriate genes which in turn allows for changes in cell morphology or activities needed for cell fate determination and cellular differentiation The Hox transcription factor family for example is important for proper body pattern formation in organisms as diverse as fruit flies to humans 23 24 Another example is the transcription factor encoded by the sex determining region Y SRY gene which plays a major role in determining sex in humans 25 Response to intercellular signals edit Cells can communicate with each other by releasing molecules that produce signaling cascades within another receptive cell If the signal requires upregulation or downregulation of genes in the recipient cell often transcription factors will be downstream in the signaling cascade 26 Estrogen signaling is an example of a fairly short signaling cascade that involves the estrogen receptor transcription factor Estrogen is secreted by tissues such as the ovaries and placenta crosses the cell membrane of the recipient cell and is bound by the estrogen receptor in the cell s cytoplasm The estrogen receptor then goes to the cell s nucleus and binds to its DNA binding sites changing the transcriptional regulation of the associated genes 27 Response to environment edit Not only do transcription factors act downstream of signaling cascades related to biological stimuli but they can also be downstream of signaling cascades involved in environmental stimuli Examples include heat shock factor HSF which upregulates genes necessary for survival at higher temperatures 28 hypoxia inducible factor HIF which upregulates genes necessary for cell survival in low oxygen environments 29 and sterol regulatory element binding protein SREBP which helps maintain proper lipid levels in the cell 30 Cell cycle control edit Many transcription factors especially some that are proto oncogenes or tumor suppressors help regulate the cell cycle and as such determine how large a cell will get and when it can divide into two daughter cells 31 32 One example is the Myc oncogene which has important roles in cell growth and apoptosis 33 Pathogenesis edit Transcription factors can also be used to alter gene expression in a host cell to promote pathogenesis A well studied example of this are the transcription activator like effectors TAL effectors secreted by Xanthomonas bacteria When injected into plants these proteins can enter the nucleus of the plant cell bind plant promoter sequences and activate transcription of plant genes that aid in bacterial infection 34 TAL effectors contain a central repeat region in which there is a simple relationship between the identity of two critical residues in sequential repeats and sequential DNA bases in the TAL effector s target site 35 36 This property likely makes it easier for these proteins to evolve in order to better compete with the defense mechanisms of the host cell 37 Regulation editIt is common in biology for important processes to have multiple layers of regulation and control This is also true with transcription factors Not only do transcription factors control the rates of transcription to regulate the amounts of gene products RNA and protein available to the cell but transcription factors themselves are regulated often by other transcription factors Below is a brief synopsis of some of the ways that the activity of transcription factors can be regulated Synthesis edit Transcription factors like all proteins are transcribed from a gene on a chromosome into RNA and then the RNA is translated into protein Any of these steps can be regulated to affect the production and thus activity of a transcription factor An implication of this is that transcription factors can regulate themselves For example in a negative feedback loop the transcription factor acts as its own repressor If the transcription factor protein binds the DNA of its own gene it down regulates the production of more of itself This is one mechanism to maintain low levels of a transcription factor in a cell 38 Nuclear localization edit In eukaryotes transcription factors like most proteins are transcribed in the nucleus but are then translated in the cell s cytoplasm Many proteins that are active in the nucleus contain nuclear localization signals that direct them to the nucleus But for many transcription factors this is a key point in their regulation 39 Important classes of transcription factors such as some nuclear receptors must first bind a ligand while in the cytoplasm before they can relocate to the nucleus 39 Activation edit Transcription factors may be activated or deactivated through their signal sensing domain by a number of mechanisms including ligand binding Not only is ligand binding able to influence where a transcription factor is located within a cell but ligand binding can also affect whether the transcription factor is in an active state and capable of binding DNA or other cofactors see for example nuclear receptors phosphorylation 40 41 Many transcription factors such as STAT proteins must be phosphorylated before they can bind DNA interaction with other transcription factors e g homo or hetero dimerization or coregulatory proteinsAccessibility of DNA binding site edit In eukaryotes DNA is organized with the help of histones into compact particles called nucleosomes where sequences of about 147 DNA base pairs make 1 65 turns around histone protein octamers DNA within nucleosomes is inaccessible to many transcription factors Some transcription factors so called pioneer factors are still able to bind their DNA binding sites on the nucleosomal DNA For most other transcription factors the nucleosome should be actively unwound by molecular motors such as chromatin remodelers 42 Alternatively the nucleosome can be partially unwrapped by thermal fluctuations allowing temporary access to the transcription factor binding site In many cases a transcription factor needs to compete for binding to its DNA binding site with other transcription factors and histones or non histone chromatin proteins 43 Pairs of transcription factors and other proteins can play antagonistic roles activator versus repressor in the regulation of the same gene Availability of other cofactors transcription factors edit Most transcription factors do not work alone Many large TF families form complex homotypic or heterotypic interactions through dimerization 44 For gene transcription to occur a number of transcription factors must bind to DNA regulatory sequences This collection of transcription factors in turn recruit intermediary proteins such as cofactors that allow efficient recruitment of the preinitiation complex and RNA polymerase Thus for a single transcription factor to initiate transcription all of these other proteins must also be present and the transcription factor must be in a state where it can bind to them if necessary Cofactors are proteins that modulate the effects of transcription factors Cofactors are interchangeable between specific gene promoters the protein complex that occupies the promoter DNA and the amino acid sequence of the cofactor determine its spatial conformation For example certain steroid receptors can exchange cofactors with NF kB which is a switch between inflammation and cellular differentiation thereby steroids can affect the inflammatory response and function of certain tissues 45 Interaction with methylated cytosine edit Transcription factors and methylated cytosines in DNA both have major roles in regulating gene expression Methylation of cytosine in DNA primarily occurs where cytosine is followed by guanine in the 5 to 3 DNA sequence a CpG site Methylation of CpG sites in a promoter region of a gene usually represses gene transcription 46 while methylation of CpGs in the body of a gene increases expression 47 TET enzymes play a central role in demethylation of methylated cytosines Demethylation of CpGs in a gene promoter by TET enzyme activity increases transcription of the gene 48 The DNA binding sites of 519 transcription factors were evaluated 49 Of these 169 transcription factors 33 did not have CpG dinucleotides in their binding sites and 33 transcription factors 6 could bind to a CpG containing motif but did not display a preference for a binding site with either a methylated or unmethylated CpG There were 117 transcription factors 23 that were inhibited from binding to their binding sequence if it contained a methylated CpG site 175 transcription factors 34 that had enhanced binding if their binding sequence had a methylated CpG site and 25 transcription factors 5 were either inhibited or had enhanced binding depending on where in the binding sequence the methylated CpG was located TET enzymes do not specifically bind to methylcytosine except when recruited see DNA demethylation Multiple transcription factors important in cell differentiation and lineage specification including NANOG SALL4A WT1 EBF1 PU 1 and E2A have been shown to recruit TET enzymes to specific genomic loci primarily enhancers to act on methylcytosine mC and convert it to hydroxymethylcytosine hmC and in most cases marking them for subsequent complete demethylation to cytosine 50 TET mediated conversion of mC to hmC appears to disrupt the binding of 5mC binding proteins including MECP2 and MBD Methyl CpG binding domain proteins facilitating nucleosome remodeling and the binding of transcription factors thereby activating transcription of those genes EGR1 is an important transcription factor in memory formation It has an essential role in brain neuron epigenetic reprogramming The transcription factor EGR1 recruits the TET1 protein that initiates a pathway of DNA demethylation 51 EGR1 together with TET1 is employed in programming the distribution of methylation sites on brain DNA during brain development and in learning see Epigenetics in learning and memory Structure edit nbsp Schematic diagram of the amino acid sequence amino terminus to the left and carboxylic acid terminus to the right of a prototypical transcription factor that contains 1 a DNA binding domain DBD 2 signal sensing domain SSD and Activation domain AD The order of placement and the number of domains may differ in various types of transcription factors In addition the transactivation and signal sensing functions are frequently contained within the same domain nbsp Domain architecture example Lactose Repressor LacI The N terminal DNA binding domain labeled of the lac repressor binds its target DNA sequence gold in the major groove using a helix turn helix motif Effector molecule binding green occurs in the regulatory domain labeled This triggers an allosteric response mediated by the linker region labeled Transcription factors are modular in structure and contain the following domains 1 DNA binding domain DBD which attaches to specific sequences of DNA enhancer or promoter Necessary component for all vectors Used to drive transcription of the vector s transgene promoter sequences adjacent to regulated genes DNA sequences that bind transcription factors are often referred to as response elements Activation domain AD which contains binding sites for other proteins such as transcription coregulators These binding sites are frequently referred to as activation functions AFs Transactivation domain TAD or Trans activating domain TAD not to be confused with topologically associating domain TAD 52 An optional signal sensing domain SSD e g a ligand binding domain which senses external signals and in response transmits these signals to the rest of the transcription complex resulting in up or down regulation of gene expression Also the DBD and signal sensing domains may reside on separate proteins that associate within the transcription complex to regulate gene expression DNA binding domain edit nbsp DNA contacts of different types of DNA binding domains of transcription factorsMain article DNA binding domain The portion domain of the transcription factor that binds DNA is called its DNA binding domain Below is a partial list of some of the major families of DNA binding domains transcription factors Family InterPro Pfam SCOPbasic helix loop helix 53 InterPro IPR001092 Pfam PF00010 SCOP 47460basic leucine zipper bZIP 54 InterPro IPR004827 Pfam PF00170 SCOP 57959C terminal effector domain of the bipartite response regulators InterPro IPR001789 Pfam PF00072 SCOP 46894AP2 ERF GCC box InterPro IPR001471 Pfam PF00847 SCOP 54176helix turn helix 55 homeodomain proteins which are encoded by homeobox genes are transcription factors Homeodomain proteins play critical roles in the regulation of development 56 57 InterPro IPR009057 Pfam PF00046 SCOP 46689lambda repressor like InterPro IPR010982 SCOP 47413srf like serum response factor InterPro IPR002100 Pfam PF00319 SCOP 55455paired box 58 winged helix InterPro IPR013196 Pfam PF08279 SCOP 46785zinc fingers 59 multi domain Cys2His2 zinc fingers 60 InterPro IPR007087 Pfam PF00096 SCOP 57667 Zn2 Cys6 SCOP 57701 Zn2 Cys8 nuclear receptor zinc finger InterPro IPR001628 Pfam PF00105 SCOP 57716Response elements edit The DNA sequence that a transcription factor binds to is called a transcription factor binding site or response element 61 Transcription factors interact with their binding sites using a combination of electrostatic of which hydrogen bonds are a special case and Van der Waals forces Due to the nature of these chemical interactions most transcription factors bind DNA in a sequence specific manner However not all bases in the transcription factor binding site may actually interact with the transcription factor In addition some of these interactions may be weaker than others Thus transcription factors do not bind just one sequence but are capable of binding a subset of closely related sequences each with a different strength of interaction For example although the consensus binding site for the TATA binding protein TBP is TATAAAA the TBP transcription factor can also bind similar sequences such as TATATAT or TATATAA Because transcription factors can bind a set of related sequences and these sequences tend to be short potential transcription factor binding sites can occur by chance if the DNA sequence is long enough It is unlikely however that a transcription factor will bind all compatible sequences in the genome of the cell Other constraints such as DNA accessibility in the cell or availability of cofactors may also help dictate where a transcription factor will actually bind Thus given the genome sequence it is still difficult to predict where a transcription factor will actually bind in a living cell Additional recognition specificity however may be obtained through the use of more than one DNA binding domain for example tandem DBDs in the same transcription factor or through dimerization of two transcription factors that bind to two or more adjacent sequences of DNA Clinical significance editTranscription factors are of clinical significance for at least two reasons 1 mutations can be associated with specific diseases and 2 they can be targets of medications Disorders edit Due to their important roles in development intercellular signaling and cell cycle some human diseases have been associated with mutations in transcription factors 62 Many transcription factors are either tumor suppressors or oncogenes and thus mutations or aberrant regulation of them is associated with cancer Three groups of transcription factors are known to be important in human cancer 1 the NF kappaB and AP 1 families 2 the STAT family and 3 the steroid receptors 63 Below are a few of the better studied examples Condition Description LocusRett syndrome Mutations in the MECP2 transcription factor are associated with Rett syndrome a neurodevelopmental disorder 64 65 Xq28Diabetes A rare form of diabetes called MODY Maturity onset diabetes of the young can be caused by mutations in hepatocyte nuclear factors HNFs 66 or insulin promoter factor 1 IPF1 Pdx1 67 multipleDevelopmental verbal dyspraxia Mutations in the FOXP2 transcription factor are associated with developmental verbal dyspraxia a disease in which individuals are unable to produce the finely coordinated movements required for speech 68 7q31Autoimmune diseases Mutations in the FOXP3 transcription factor cause a rare form of autoimmune disease called IPEX 69 Xp11 23 q13 3Li Fraumeni syndrome Caused by mutations in the tumor suppressor p53 70 17p13 1Breast cancer The STAT family is relevant to breast cancer 71 multipleMultiple cancers The HOX family are involved in a variety of cancers 72 multipleOsteoarthritis Mutation or reduced activity of SOX9 73 Potential drug targets edit See also Therapeutic gene modulation Approximately 10 of currently prescribed drugs directly target the nuclear receptor class of transcription factors 74 Examples include tamoxifen and bicalutamide for the treatment of breast and prostate cancer respectively and various types of anti inflammatory and anabolic steroids 75 In addition transcription factors are often indirectly modulated by drugs through signaling cascades It might be possible to directly target other less explored transcription factors such as NF kB with drugs 76 77 78 79 Transcription factors outside the nuclear receptor family are thought to be more difficult to target with small molecule therapeutics since it is not clear that they are drugable but progress has been made on Pax2 80 81 and the notch pathway 82 Role in evolution editFurther information Evolutionary developmental biology Gene duplications have played a crucial role in the evolution of species This applies particularly to transcription factors Once they occur as duplicates accumulated mutations encoding for one copy can take place without negatively affecting the regulation of downstream targets However changes of the DNA binding specificities of the single copy Leafy transcription factor which occurs in most land plants have recently been elucidated In that respect a single copy transcription factor can undergo a change of specificity through a promiscuous intermediate without losing function Similar mechanisms have been proposed in the context of all alternative phylogenetic hypotheses and the role of transcription factors in the evolution of all species 83 84 Role in biocontrol activity editThe transcription factors have a role in resistance activity which is important for successful biocontrol activity The resistant to oxidative stress and alkaline pH sensing were contributed from the transcription factor Yap1 and Rim101 of the Papiliotrema terrestris LS28 as molecular tools revealed an understanding of the genetic mechanisms underlying the biocontrol activity which supports disease management programs based on biological and integrated control 85 Analysis editThere are different technologies available to analyze transcription factors On the genomic level DNA sequencing 86 and database research are commonly used 87 The protein version of the transcription factor is detectable by using specific antibodies The sample is detected on a western blot By using electrophoretic mobility shift assay EMSA 88 the activation profile of transcription factors can be detected A multiplex approach for activation profiling is a TF chip system where several different transcription factors can be detected in parallel The most commonly used method for identifying transcription factor binding sites is chromatin immunoprecipitation ChIP 89 This technique relies on chemical fixation of chromatin with formaldehyde followed by co precipitation of DNA and the transcription factor of interest using an antibody that specifically targets that protein The DNA sequences can then be identified by microarray or high throughput sequencing ChIP seq to determine transcription factor binding sites If no antibody is available for the protein of interest DamID may be a convenient alternative 90 Classes editAs described in more detail below transcription factors may be classified by their 1 mechanism of action 2 regulatory function or 3 sequence homology and hence structural similarity in their DNA binding domains Mechanistic edit There are two mechanistic classes of transcription factors General transcription factors are involved in the formation of a preinitiation complex The most common are abbreviated as TFIIA TFIIB TFIID TFIIE TFIIF and TFIIH They are ubiquitous and interact with the core promoter region surrounding the transcription start site s of all class II genes 91 Upstream transcription factors are proteins that bind somewhere upstream of the initiation site to stimulate or repress transcription These are roughly synonymous with specific transcription factors because they vary considerably depending on what recognition sequences are present in the proximity of the gene 92 Examples of specific transcription factors 92 Factor Structural type Recognition sequence Binds asSP1 Zinc finger 5 GGGCGG 3 MonomerAP 1 Basic zipper 5 TGA G C TCA 3 DimerC EBP Basic zipper 5 ATTGCGCAAT 3 DimerHeat shock factor Basic zipper 5 XGAAX 3 TrimerATF CREB Basic zipper 5 TGACGTCA 3 Dimerc Myc Basic helix loop helix 5 CACGTG 3 DimerOct 1 Helix turn helix 5 ATGCAAAT 3 MonomerNF 1 Novel 5 TTGGCXXXXXGCCAA 3 Dimer G C G or C X A T G or CFunctional edit Transcription factors have been classified according to their regulatory function 12 I constitutively active present in all cells at all times general transcription factors Sp1 NF1 CCAAT II conditionally active requires activation II A developmental cell specific expression is tightly controlled but once expressed require no additional activation GATA HNF PIT 1 MyoD Myf5 Hox Winged Helix II B signal dependent requires external signal for activation II B 1 extracellular ligand endocrine or paracrine dependent nuclear receptors II B 2 intracellular ligand autocrine dependent activated by small intracellular molecules SREBP p53 orphan nuclear receptors II B 3 cell membrane receptor dependent second messenger signaling cascades resulting in the phosphorylation of the transcription factor II B 3 a resident nuclear factors reside in the nucleus regardless of activation state CREB AP 1 Mef2 II B 3 b latent cytoplasmic factors inactive form reside in the cytoplasm but when activated are translocated into the nucleus STAT R SMAD NF kB Notch TUBBY NFATStructural edit Transcription factors are often classified based on the sequence similarity and hence the tertiary structure of their DNA binding domains 93 11 94 10 1 Superclass Basic Domains 1 1 Class Leucine zipper factors bZIP 1 1 1 Family AP 1 like components includes c Fos c Jun 1 1 2 Family CREB 1 1 3 Family C EBP like factors 1 1 4 Family bZIP PAR 1 1 5 Family Plant G box binding factors 1 1 6 Family ZIP only 1 2 Class Helix loop helix factors bHLH 1 2 1 Family Ubiquitous class A factors 1 2 2 Family Myogenic transcription factors MyoD 1 2 3 Family Achaete Scute 1 2 4 Family Tal Twist Atonal Hen 1 3 Class Helix loop helix leucine zipper factors bHLH ZIP 1 3 1 Family Ubiquitous bHLH ZIP factors includes USF USF1 USF2 SREBP SREBP 1 3 2 Family Cell cycle controlling factors includes c Myc 1 4 Class NF 1 1 4 1 Family NF 1 A B C X 1 5 Class RF X 1 5 1 Family RF X 1 2 3 4 5 ANK 1 6 Class bHSH 2 Superclass Zinc coordinating DNA binding domains 2 1 Class Cys4 zinc finger of nuclear receptor type 2 1 1 Family Steroid hormone receptors 2 1 2 Family Thyroid hormone receptor like factors 2 2 Class diverse Cys4 zinc fingers 2 2 1 Family GATA Factors 2 3 Class Cys2His2 zinc finger domain 2 3 1 Family Ubiquitous factors includes TFIIIA Sp1 2 3 2 Family Developmental cell cycle regulators includes Kruppel 2 3 4 Family Large factors with NF 6B like binding properties 2 4 Class Cys6 cysteine zinc cluster 2 5 Class Zinc fingers of alternating composition 3 Superclass Helix turn helix 3 1 Class Homeo domain 3 1 1 Family Homeo domain only includes Ubx 3 1 2 Family POU domain factors includes Oct 3 1 3 Family Homeo domain with LIM region 3 1 4 Family homeo domain plus zinc finger motifs 3 2 Class Paired box 3 2 1 Family Paired plus homeo domain 3 2 2 Family Paired domain only 3 3 Class Fork head winged helix 3 3 1 Family Developmental regulators includes forkhead 3 3 2 Family Tissue specific regulators 3 3 3 Family Cell cycle controlling factors 3 3 0 Family Other regulators 3 4 Class Heat Shock Factors 3 4 1 Family HSF 3 5 Class Tryptophan clusters 3 5 1 Family Myb 3 5 2 Family Ets type 3 5 3 Family Interferon regulatory factors 3 6 Class TEA transcriptional enhancer factor domain 3 6 1 Family TEA TEAD1 TEAD2 TEAD3 TEAD4 4 Superclass beta Scaffold Factors with Minor Groove Contacts 4 1 Class RHR Rel homology region 4 1 1 Family Rel ankyrin NF kappaB 4 1 2 Family ankyrin only 4 1 3 Family NFAT Nuclear Factor of Activated T cells NFATC1 NFATC2 NFATC3 4 2 Class STAT 4 2 1 Family STAT 4 3 Class p53 4 3 1 Family p53 4 4 Class MADS box 4 4 1 Family Regulators of differentiation includes Mef2 4 4 2 Family Responders to external signals SRF serum response factor SRF 4 4 3 Family Metabolic regulators ARG80 4 5 Class beta Barrel alpha helix transcription factors 4 6 Class TATA binding proteins 4 6 1 Family TBP 4 7 Class HMG box 4 7 1 Family SOX genes SRY 4 7 2 Family TCF 1 TCF1 4 7 3 Family HMG2 related SSRP1 4 7 4 Family UBF 4 7 5 Family MATA 4 8 Class Heteromeric CCAAT factors 4 8 1 Family Heteromeric CCAAT factors 4 9 Class Grainyhead 4 9 1 Family Grainyhead 4 10 Class Cold shock domain factors 4 10 1 Family csd 4 11 Class Runt 4 11 1 Family Runt 0 Superclass Other Transcription Factors 0 1 Class Copper fist proteins 0 2 Class HMGI Y HMGA1 0 2 1 Family HMGI Y 0 3 Class Pocket domain 0 4 Class E1A like factors 0 5 Class AP2 EREBP related factors 0 5 1 Family AP2 0 5 2 Family EREBP 0 5 3 Superfamily AP2 B3 0 5 3 1 Family ARF 0 5 3 2 Family ABI 0 5 3 3 Family RAVTranscription factor databases editThere are numerous databases cataloging information about transcription factors but their scope and utility vary dramatically Some may contain only information about the actual proteins some about their binding sites or about their target genes Examples include the following footprintDB a metadatabase of multiple databases including JASPAR and others JASPAR database of transcription factor binding sites for eukaryotes PlantTFD Plant transcription factor database 95 TcoF DB Database of transcription co factors and transcription factor interactions 96 TFcheckpoint database of human mouse and rat TF candidates transcriptionfactor org now commercial selling reagents MethMotif org An integrative cell specific database of transcription factor binding motifs coupled with DNA methylation profiles 97 See also editCdx protein family DNA binding protein Inhibitor of DNA binding protein Mapper 2 Nuclear receptor a class of ligand activated transcription factors Open Regulatory Annotation Database Phylogenetic footprinting TRANSFAC database YeTFaSCoReferences edit a b Latchman DS December 1997 Transcription factors an overview The International Journal of Biochemistry amp Cell Biology 29 12 1305 12 doi 10 1016 S1357 2725 97 00085 X PMC 2002184 PMID 9570129 Karin M February 1990 Too many transcription factors positive and negative interactions The New Biologist 2 2 126 31 PMID 2128034 a b Babu MM Luscombe NM Aravind L Gerstein M Teichmann SA June 2004 Structure and evolution of transcriptional regulatory networks PDF Current Opinion in Structural Biology 14 3 283 91 doi 10 1016 j sbi 2004 05 004 PMID 15193307 How Genes are Regulated Transcription Factors on YouTube Roeder RG September 1996 The role of general initiation factors in transcription by RNA polymerase II Trends in Biochemical Sciences 21 9 327 35 doi 10 1016 S0968 0004 96 10050 5 PMID 8870495 Nikolov DB Burley SK January 1997 RNA polymerase II transcription initiation a structural view Proceedings of the National Academy of Sciences of the United States of America 94 1 15 22 Bibcode 1997PNAS 94 15N doi 10 1073 pnas 94 1 15 PMC 33652 PMID 8990153 Lee TI Young RA 2000 Transcription of eukaryotic protein coding genes Annual Review of Genetics 34 77 137 doi 10 1146 annurev genet 34 1 77 PMID 11092823 Mitchell PJ Tjian R July 1989 Transcriptional regulation in mammalian cells by sequence specific DNA binding proteins Science 245 4916 371 8 Bibcode 1989Sci 245 371M doi 10 1126 science 2667136 PMID 2667136 Ptashne M Gann A April 1997 Transcriptional activation by recruitment Nature 386 6625 569 77 Bibcode 1997Natur 386 569P doi 10 1038 386569a0 PMID 9121580 S2CID 6203915 a b Jin J Zhang H Kong L Gao G Luo J January 2014 PlantTFDB 3 0 a portal for the functional and evolutionary study of plant transcription factors Nucleic Acids Research 42 Database issue D1182 7 doi 10 1093 nar gkt1016 PMC 3965000 PMID 24174544 a b Matys V Kel Margoulis OV Fricke E Liebich I Land S Barre Dirrie A Reuter I Chekmenev D Krull M Hornischer K Voss N Stegmaier P Lewicki Potapov B Saxel H Kel AE Wingender E January 2006 TRANSFAC and its module TRANSCompel transcriptional gene regulation in eukaryotes Nucleic Acids Research 34 Database issue D108 10 doi 10 1093 nar gkj143 PMC 1347505 PMID 16381825 a b c Brivanlou AH Darnell JE February 2002 Signal transduction and the control of gene expression Science 295 5556 813 8 Bibcode 2002Sci 295 813B doi 10 1126 science 1066355 PMID 11823631 S2CID 14954195 van Nimwegen E September 2003 Scaling laws in the functional content of genomes Trends in Genetics 19 9 479 84 arXiv physics 0307001 doi 10 1016 S0168 9525 03 00203 8 PMID 12957540 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2007 Jin J Tian F Yang DC Meng YQ Kong L Luo J Gao G January 2017 PlantTFDB 4 0 toward a central hub for transcription factors and regulatory interactions in plants Nucleic Acids Research 45 D1 D1040 D1045 doi 10 1093 nar gkw982 PMC 5210657 PMID 27924042 Schmeier S Alam T Essack M Bajic VB January 2017 TcoF DB v2 update of the database of human and mouse transcription co factors and transcription factor interactions Nucleic Acids Research 45 D1 D145 D150 doi 10 1093 nar gkw1007 PMC 5210517 PMID 27789689 Xuan Lin QX Sian S An O Thieffry D Jha S Benoukraf T January 2019 MethMotif an integrative cell specific database of transcription factor binding motifs coupled with DNA methylation profiles Nucleic Acids Research 47 D1 D145 D154 doi 10 1093 nar gky1005 PMC 6323897 PMID 30380113 Further reading editCarretero Paulet Lorenzo Galstyan Anahit Roig Villanova Irma Martinez Garcia Jaime F Bilbao Castro Jose R Genome Wide Classification and Evolutionary Analysis of the bHLH Family of Transcription Factors in Arabidopsis Poplar Rice Moss and Algae Plant Physiology 153 3 2010 07 pag 1398 1412 doi 10 1104 pp 110 153593 ISSN 0032 0889 Jin J He K Tang X Li Z Lv L Zhao Y Luo J Gao G 2015 An Arabidopsis Transcriptional Regulatory Map Reveals Distinct Functional and Evolutionary Features of Novel Transcription Factors Molecular Biology and Evolution 32 7 1767 73 doi 10 1093 molbev msv058 PMC 4476157 PMID 25750178 Lambert S Jolma A Campitelli L Pratyush Z Das K Yin Y Albu M Chen X Taipae J Hughes T Weirauch M 2018 The Human Transcription Factors Cell 172 4 650 665 doi 10 1016 j cell 2018 01 029 PMID 29425488 External links editTranscription Factors at the U S National Library of Medicine Medical Subject Headings MeSH Transcription factor database Archived 4 December 2008 at the Wayback Machine Retrieved from https en wikipedia org w index php title Transcription factor amp oldid 1192527283, wikipedia, wiki, book, books, library,

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