In
molecular biology
Molecular biology is a branch of biology that seeks to understand the molecule, molecular basis of biological activity in and between Cell (biology), cells, including biomolecule, biomolecular synthesis, modification, mechanisms, and interactio ...
, the iron response element or iron-responsive element (IRE) is a short conserved
stem-loop
Stem-loops are nucleic acid Biomolecular structure, secondary structural elements which form via intramolecular base pairing in single-stranded DNA or RNA. They are also referred to as hairpins or hairpin loops. A stem-loop occurs when two regi ...
which is bound by
iron response proteins (IRPs, also named IRE-BP or IRBP). The IRE is found in
UTRs (untranslated regions) of various
mRNA
In molecular biology, messenger ribonucleic acid (mRNA) is a single-stranded molecule of RNA that corresponds to the genetic sequence of a gene, and is read by a ribosome in the process of Protein biosynthesis, synthesizing a protein.
mRNA is ...
s whose products are involved in
iron metabolism. For example, the mRNA of
ferritin
Ferritin is a universal intracellular and extracellular protein that stores iron and releases it in a controlled fashion. The protein is produced by almost all living organisms, including archaea, bacteria, algae, higher plants, and animals. ...
(an iron storage protein) contains one IRE in its
5' UTR
The 5′ untranslated region (also known as 5′ UTR, leader sequence, transcript leader, or leader RNA) is the region of a messenger RNA (mRNA) that is directly Upstream and downstream (DNA), upstream from the initiation codon. This region is im ...
. When iron concentration is low, IRPs bind the IRE in the ferritin mRNA and cause reduced translation rates. In contrast, binding to multiple IREs in the
3' UTR
In molecular genetics, the three prime untranslated region (3′-UTR) is the section of messenger RNA (mRNA) that immediately follows the translation (biology), translation termination codon. The 3′-UTR often contains regulatory regions that P ...
of the
transferrin receptor (involved in iron acquisition) leads to increased
mRNA stability.
Mechanism of action
The two leading theories describe how iron probably interacts to impact posttranslational control of transcription. The classical theory suggests that IRPs, in the absence of iron, bind avidly to the mRNA IRE. When iron is present, it interacts with the protein to cause it to release the mRNA. For example, In high iron conditions in humans, IRP1 binds with an iron-sulphur complex
Fe-4Sand adopts an aconitase conformation unsuitable for IRE binding. In contrast, IRP2 is degraded in high iron conditions. There is variation in affinity between different IREs and different IRPs.
In the second theory two proteins compete for the IRE binding site—both IRP and eukaryotic Initiation Factor 4F (eIF4F). In the absence of iron IRP binds about 10 times more avidly than the initiation factor. However, when Iron interacts at the IRE, it causes the mRNA to change its shape, thus favoring the binding of the eIF4F. Several studies have identified non-canonical IREs. It has also been shown that IRP binds to some IREs better than others.
Structural details. The upper helix of the known IREs shows stronger conservation of structure compared to the lower helix. The bases composing the helixes are variable. The mid-stem bulged C is a highly characteristic feature (though this has been seen to be a G in the ferritin IRE for lobster). The apical loop of the known IREs all consist of either the AGA or AGU triplet. This is pinched by a paired G-C and there is additionally a bulged U, C or A in the upper helix. The crystal structure and NMR data show a bulged U in the lower stem of the ferritin IRE. This is consistent with the predicted secondary structure. IREs in many other mRNAs do not have any support for this bulged U. Consequently, two RFAM models have been created for the IRE—one with a bulged U and one without.
Genes with IREs
Genes known to contain IREs include
FTH1,
FTL,
TFRC,
ALAS2, Sdhb,
ACO2, Hao1,
SLC11A2 (encoding DMT1),
NDUFS1,
SLC40A1 (encoding the ferroportin)
CDC42BPA ,
CDC14A,
EPAS1.
In humans, 12 genes have been shown to be transcribed with the canonical IRE structure, but several mRNA structures, that are non-canonical, have been shown to interact with IRPs and be influenced by iron concentration. Software and algorithms have been developed to locate more genes that are also responsive to iron concentration.
Taxonomic range. The IRE is found over a diverse taxonomic range—mainly eukaryotes but not in plants.
Processes regulated by IREs
Many genes regulated by IREs have clear and direct roles in iron metabolism. Others show a less obvious connection. ACO2 encodes an isomerase catalysing the reversible isomerisation of citrate and
isocitrate. EPAS1 encodes a
transcription factor
In molecular biology, a transcription factor (TF) (or sequence-specific DNA-binding factor) is a protein that controls the rate of transcription (genetics), transcription of genetics, genetic information from DNA to messenger RNA, by binding t ...
involved in complex oxygen sensing pathways by the induction of oxygen regulated genes under low oxygen conditions. CDC42BPA encodes a
kinase with a role in cytoskeletal reorganisation. CDC14A encodes a dual-specificity phosphatase implicated in cell cycle control and also interacts with interphase centrosomes.
See also
*
5'UTR
*
IRP
References
External links
*
*
Transterm page for Iron Responsive ElementGenomic Interval files with IRE predictions made using the RFAM models on the hg18 human genome
{{DEFAULTSORT:Iron Response Element
Cis-regulatory RNA elements
Articles containing video clips