Internal transcribed spacer

Internal transcribed spacer (ITS) is the spacer DNA situated between the small-subunit ribosomal RNA (rRNA) and large-subunit rRNA genes in the chromosome or the corresponding transcribed region in the polycistronic rRNA precursor transcript.

ITS across life domains

In bacteria and archaea, there is a single ITS, located between the 16S and 23S rRNA genes. Contrastingly, there are two ITSs in eukaryotes: ITS1 is located between 18S and 5.8S rRNA genes, while ITS2 is between 5.8S and 28S (in opisthokonts, or 25S in plants) rRNA genes. ITS1 corresponds to the ITS in bacteria and archaea, while ITS2 originated as an insertion that interrupted the ancestral 23S rRNA gene.[1][2]

Organization

Organization of the eukaryotic nuclear ribosomal DNA tandem repeats

In bacteria and archaea, the ITS occurs in one to several copies, as do the flanking 16S and 23S genes. When there are multiple copies, these do not occur adjacent to one another. Rather, they occur in discrete locations in the circular chromosome.

In eukaryotes, genes encoding ribosomal RNA and spacers occur in tandem repeats that are thousands of copies long, each separated by regions of non-transcribed DNA termed intergenic spacer (IGS) or non-transcribed spacer (NTS).

Each eukaryotic ribosomal cluster contains the 5' external transcribed spacer (5' ETS), the 18S rRNA gene, the ITS1, the 5.8S rRNA gene, the ITS2, the 26S or 28S rRNA gene, and finally the 3' ETS.[3]

During rRNA maturation, ETS and ITS pieces are excised. As non-functional by-products of this maturation, they are rapidly degraded.[4]

Use in phylogeny

Sequence comparison of the ITS region is widely used in taxonomy and molecular phylogeny because of several favorable properties:[5]

  • It is routinely amplified thanks to its small size associated to the availability of highly conserved flanking sequences.
  • It is easy to detect even from small quantities of DNA due to the high copy number of the rRNA clusters.
  • It undergoes rapid concerted evolution via unequal crossing-over and gene conversion. This promotes intra-genomic homogeneity of the repeat units, although high-throughput sequencing showed the occurrence of frequent variations within plant species.[6]
  • It has a high degree of variation even between closely related species. This can be explained by the relatively low evolutionary pressure acting on such non-coding spacer sequences.

For example, ITS markers have proven especially useful for elucidating phylogenetic relationships among the following taxa.

Taxonomic group Taxonomic level Year Authors with references
Asteraceae: Compositae Species (congeneric) 1992 Baldwin et al.[7]
Viscaceae: Arceuthobium Species (congeneric) 1994 Nickrent et al.[8]
Poaceae: Zea Species (congeneric) 1996 Buckler & Holtsford[9]
Leguminosae: Medicago Species (congeneric) 1998 Bena et al.[3]
Orchidaceae: Diseae Genera (within tribes) 1999 Douzery et al.[10]
Odonota: Calopteryx Species (congeneric) 2001 Weekers et al.[11]
Yeasts of clinical importance Genera 2001 Chen et al.[12]
Poaceae: Saccharinae Genera (within tribes) 2002 Hodkinson et al.[13]
Plantaginaceae: Plantago Species (congeneric) 2002 Rønsted et al.[14]
Jungermanniopsida: Herbertus Species (congeneric) 2004 Feldberg et al.[15]
Pinaceae: Tsuga Species (congeneric) 2008 Havill et al.[16]
Chrysomelidae: Altica Genera (congeneric) 2009 Ruhl et al.[17]
Symbiodinium Clade 2009 Stat et al.[18]
Brassicaceae Tribes (within a family) 2010 Warwick et al.[19]
Ericaceae: Erica Species (congeneric) 2011 Pirie et al.[20]
Diptera: Bactrocera Species (congeneric) 2014 Boykin et al.[21]
Scrophulariaceae: Scrophularia Species (congeneric) 2014 Scheunert & Heubl[22]
Potamogetonaceae: Potamogeton Species (congeneric) 2016 Yang et al.[23]

Mycological barcoding

The ITS region is the most widely sequenced DNA region in molecular ecology of fungi[24] and has been recommended as the universal fungal barcode sequence.[25] It has typically been most useful for molecular systematics at the species to genus level, and even within species (e.g., to identify geographic races). Because of its higher degree of variation than other genic regions of rDNA (for example, small- and large-subunit rRNA), variation among individual rDNA repeats can sometimes be observed within both the ITS and IGS regions. In addition to the universal ITS1+ITS4 primers[26] used by many labs, several taxon-specific primers have been described that allow selective amplification of fungal sequences (e.g., see Gardes & Bruns 1993 paper describing amplification of basidiomycete ITS sequences from mycorrhiza samples).[27] Despite shotgun sequencing methods becoming increasingly utilized in microbial sequencing, the low biomass of fungi in clinical samples make the ITS region amplification an area of ongoing research.[28][29]

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References

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  2. Scott Orland Rogers (27 July 2011). Integrated Molecular Evolution. CRC Press. pp. 65–66. ISBN 978-1-4398-1995-1. Retrieved 9 March 2015.
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  6. Song, Jingyuan; Shi, Linchun; Li, Dezhu; Sun, Yongzhen; Niu, Yunyun; Chen, Zhiduan; Luo, Hongmei; Pang, Xiaohui; Sun, Zhiying (2012-08-30). "Extensive Pyrosequencing Reveals Frequent Intra-Genomic Variations of Internal Transcribed Spacer Regions of Nuclear Ribosomal DNA". PLOS ONE. 7 (8): e43971. Bibcode:2012PLoSO...743971S. doi:10.1371/journal.pone.0043971. ISSN 1932-6203. PMC 3431384. PMID 22952830.
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