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. 2021 May 27;13(11):2643. doi: 10.3390/cancers13112643

Table 1.

Comparison of commonly used methods for lncRNA structural studies.

Type of Experiment Limitations Methods Structure lncRNA References
In vitro
  • Controlled conditions, lncRNA structure more stable than in in vivo tests

  • Requires sequencing

Enzymatic probing
  • Only in vitro

  • Fragmentation of RNA by nucleases makes difficult the identification of secondary structures at single-nucleotide level

  • Might require additional probing with nuclease or chemical

PARS/nuclease S1 and RNaseV1 double- and single-
stranded regions of RNA
Rox1
Rox2
[73]
Chemical probing
  • Does not provide information concerning interactions between base-pairing (at close- or long-range)

  • Labour-intensive

SHAPE-seq 2′-OH acylation Braveheart RepA
Rox1
Rox2
SRA HOTAIR COOLAIR MALAT1 NEAT1
[66,67,68,69,71,73,74,75]
  • DMS- nucleotide bias (only able to react with purines)

  • DMS is corrosive and toxic,

  • In some cases, using DMS is not sufficient to capture all single-stranded regions

  • Labour-intensive

DMS-seq (DMS) unpaired adenine and cytosine
residues
BraveheartRepA
SRA HOTAIR MALAT1
[66,67,69,74,75]
In vivo
  • Requires sequencing

  • Difficult task due to lncRNAs’ size and low abundance in cells

  • lncRNAs are expressed in alternative isoforms and bound by a variety of RNA binding proteins in vivo

Chemical Probing:
SHAPE-MaP (1M7,1M6,NMI1) 2′-OH acylation Xist [55]
In silico
  • lncRNA is more structured than in in vivo tests

  • Only for prediction of secondary structure

  • Has to be complemented by in vivo/in vitro tests

CROSS (Computational Recognition of Secondary Structure) RepA,
D2 domain
Xist HOTAIR [76]
Biophysical
  • Difficult for application of higher numbers of transcripts

  • Difficult for long RNA strands

  • Requires large quantities of robust, homogenous sample

  • Crystallography is labour-intensive

X-ray A-rich 3′-UTR MALAT1 [77]
NMR spectroscopy AUCG tetraloop Xist [56]