Noncoding RNAs belong to several groups and are involved in many cellular processes. These range from ncRNAs of central importance that are conserved across all or most cellular life through to more transient ncRNAs specific to one or a few closely related species. The more conserved ncRNAs are thought to be
molecular fossils or relics from the
last universal common ancestor and the
RNA world, and their current roles remain mostly in regulation of information flow from DNA to protein. . Proteins are shown in blue and the two RNA strands in orange and yellow. The small patch of green in the center of the subunit is the active site.
In translation Many of the conserved, essential and abundant ncRNAs are involved in
translation.
Ribonucleoprotein (RNP) particles called
ribosomes are the 'factories' where translation takes place in the cell. The ribosome consists of more than 60%
ribosomal RNA; these are made up of 3 ncRNAs in
prokaryotes and 4 ncRNAs in
eukaryotes. Ribosomal RNAs catalyse the translation of nucleotide sequences to protein. Another set of ncRNAs,
Transfer RNAs, form an 'adaptor molecule' between
mRNA and protein. The
H/ACA box and C/D box snoRNAs are ncRNAs found in archaea and eukaryotes.
RNase MRP is restricted to eukaryotes. Both groups of ncRNA are involved in the maturation of rRNA. The snoRNAs guide covalent modifications of rRNA, tRNA and
snRNAs; RNase MRP cleaves the
internal transcribed spacer 1 between 18S and 5.8S rRNAs. The ubiquitous ncRNA,
RNase P, is an evolutionary relative of RNase MRP. RNase P matures tRNA sequences by generating mature 5'-ends of tRNAs through cleaving the 5'-leader elements of precursor-tRNAs. Another ubiquitous RNP called
SRP recognizes and transports specific nascent proteins to the
endoplasmic reticulum in
eukaryotes and the
plasma membrane in
prokaryotes. In bacteria,
Transfer-messenger RNA (tmRNA) is an RNP involved in rescuing stalled ribosomes, tagging incomplete
polypeptides and promoting the degradation of aberrant mRNA.
In RNA splicing In eukaryotes, the
spliceosome performs the
splicing reactions essential for removing
intron sequences, this process is required for the formation of mature
mRNA. The
spliceosome is another RNP often known as the
snRNP or tri-snRNP. There are two different forms of the spliceosome, the major and minor forms. The ncRNA components of the major spliceosome are
U1,
U2,
U4,
U5, and
U6. The ncRNA components of the minor spliceosome are
U11,
U12,
U5,
U4atac and
U6atac. Another group of introns can catalyse their own removal from host transcripts; these are called self-splicing RNAs. There are two main groups of self-splicing RNAs:
group I catalytic intron and
group II catalytic intron. These ncRNAs catalyze their own excision from mRNA, tRNA and rRNA precursors in a wide range of organisms. In mammals it has been found that snoRNAs can also regulate the
alternative splicing of mRNA, for example snoRNA
HBII-52 regulates the splicing of
serotonin receptor 2C. In nematodes, the
SmY ncRNA appears to be involved in mRNA
trans-splicing.
In DNA replication protein (white) binds the end of a double-stranded Y RNA (red) and a single stranded RNA (blue). (PDB: 1YVP
Y RNAs are stem loops, necessary for
DNA replication through interactions with
chromatin and initiation proteins (including the
origin recognition complex). They are also components of the
Ro60 ribonucleoprotein particle which is a target of autoimmune antibodies in patients with
systemic lupus erythematosus.
In gene regulation The
expression of many thousands of
genes are regulated by ncRNAs. This regulation can occur in
trans or in
cis. There is increasing evidence that a special type of ncRNAs called
enhancer RNAs, transcribed from the enhancer region of a gene, act to promote gene expression.
Trans-acting In higher eukaryotes
microRNAs regulate gene expression. A single miRNA can reduce the expression levels of hundreds of genes. The mechanism by which mature miRNA molecules act is through partial complementarity to one or more messenger RNA (mRNA) molecules, generally in
3' UTRs. The main function of miRNAs is to down-regulate gene expression. The ncRNA
RNase P has also been shown to influence gene expression. In the human nucleus,
RNase P is required for the normal and efficient transcription of various ncRNAs transcribed by
RNA polymerase III. These include tRNA,
5S rRNA,
SRP RNA, and
U6 snRNA genes. RNase P exerts its role in transcription through association with Pol III and
chromatin of active tRNA and 5S rRNA genes. It has been shown that
7SK RNA, a
metazoan ncRNA, acts as a negative regulator of the
RNA polymerase II elongation factor P-TEFb, and that this activity is influenced by stress response pathways. The bacterial ncRNA,
6S RNA, specifically associates with RNA polymerase holoenzyme containing the
sigma70 specificity factor. This interaction represses expression from a sigma70-dependent
promoter during
stationary phase. Another bacterial ncRNA,
OxyS RNA represses translation by binding to
Shine-Dalgarno sequences thereby occluding ribosome binding. OxyS RNA is induced in response to oxidative stress in Escherichia coli. The B2 RNA is a small noncoding RNA polymerase III transcript that represses mRNA transcription in response to heat shock in mouse cells. B2 RNA inhibits transcription by binding to core Pol II. Through this interaction, B2 RNA assembles into preinitiation complexes at the promoter and blocks RNA synthesis. A recent study has shown that just the act of transcription of ncRNA sequence can have an influence on gene expression.
RNA polymerase II transcription of ncRNAs is required for
chromatin remodelling in the
Schizosaccharomyces pombe. Chromatin is progressively converted to an open configuration, as several species of ncRNAs are transcribed.
Cis-acting A number of ncRNAs are embedded in the 5'
UTRs (Untranslated Regions) of
protein coding genes and influence their expression in various ways. For example, a
riboswitch can directly bind a
small target molecule; the binding of the target affects the gene's activity.
RNA leader sequences are found upstream of the first gene of amino acid biosynthetic operons. These
RNA elements form one of two possible structures in regions encoding very short peptide sequences that are rich in the end product amino acid of the operon. A terminator structure forms when there is an excess of the regulatory amino acid and ribosome movement over the leader transcript is not impeded. When there is a deficiency of the charged tRNA of the regulatory amino acid the ribosome translating the leader peptide stalls and the antiterminator structure forms. This allows RNA polymerase to transcribe the operon. Known RNA leaders are
Histidine operon leader,
Leucine operon leader,
Threonine operon leader and the
Tryptophan operon leader.
Iron response elements (IRE) are bound by
iron response proteins (IRP). The IRE is found in UTRs of various
mRNAs whose products are involved in
iron metabolism. When iron concentration is low, IRPs bind the ferritin mRNA IRE leading to translation repression.
Internal ribosome entry sites (IRES) are
RNA structures that allow for
translation initiation in the middle of a mRNA sequence as part of the process of
protein synthesis.
In genome defense Piwi-interacting RNAs (piRNAs) expressed in
mammalian
testes and
somatic cells form RNA-protein complexes with
Piwi proteins. These piRNA complexes (piRCs) have been linked to transcriptional gene silencing of
retrotransposons and other genetic elements in
germline cells, particularly those in
spermatogenesis.
Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) are repeats found in the
DNA of many
bacteria and
archaea. The repeats are separated by spacers of similar length. It has been demonstrated that these spacers can be derived from phage and subsequently help protect the cell from infection.
Chromosome structure Telomerase is an RNP
enzyme that adds specific
DNA sequence repeats ("TTAGGG" in vertebrates) to
telomeric regions, which are found at the ends of eukaryotic
chromosomes. The telomeres contain condensed DNA material, giving stability to the chromosomes. The enzyme is a
reverse transcriptase that carries
Telomerase RNA, which is used as a template when it elongates telomeres, which are shortened after each
replication cycle.
Xist (X-inactive-specific transcript) is a long ncRNA gene on the
X chromosome of the
placental mammals that acts as major effector of the
X chromosome inactivation process forming
Barr bodies. An
antisense RNA,
Tsix, is a negative regulator of Xist. X chromosomes lacking Tsix expression (and thus having high levels of Xist transcription) are inactivated more frequently than normal chromosomes. In
drosophilids, which also use an
XY sex-determination system, the
roX (RNA on the X) RNAs are involved in dosage compensation. Both Xist and roX operate by
epigenetic regulation of transcription through the recruitment of
histone-modifying enzymes.
Bifunctional RNA Bifunctional RNAs, or
dual-function RNAs, are RNAs that have two distinct functions. The majority of the known bifunctional RNAs are mRNAs that encode both a protein and ncRNAs. However, a growing number of ncRNAs fall into two different ncRNA categories; e.g.,
H/ACA box snoRNA and
miRNA. Two well known examples of bifunctional RNAs are
SgrS RNA and
RNAIII. However, a handful of other bifunctional RNAs are known to exist (e.g., steroid receptor activator/SRA, VegT RNA, Oskar RNA,
ENOD40, p53 RNA
SR1 RNA, and
Spot 42 RNA.) Bifunctional RNAs were the subject of a 2011 special issue of
Biochimie.
As a hormone There is an important link between certain non-coding RNAs and the control of hormone-regulated pathways. In
Drosophila, hormones such as
ecdysone and
juvenile hormone can promote the expression of certain miRNAs. Furthermore, this regulation occurs at distinct temporal points within
Caenorhabditis elegans development. In mammals,
miR-206 is a crucial regulator of
estrogen-receptor-alpha. Non-coding RNAs are crucial in the development of several endocrine organs, as well as in endocrine diseases such as
diabetes mellitus. Specifically in the MCF-7 cell line, addition of 17β-
estradiol increased global transcription of the noncoding RNAs called
long noncoding RNAs (lncRNAs) near estrogen-activated coding genes.
In pathogenic avoidance C. elegans was shown to learn and inherit
pathogenic avoidance after exposure to a single non-coding RNA of a
bacterial pathogen. ==Roles in disease==