JUMPING GENES AND RNA BRIDGES – SCIENCE

JUMPING GENES AND RNA BRIDGES – SCIENCE
News: Scientists at the Carnegie Institution found that some genes were able to move around within the genome. These genes were called Jumping genes or transposons.

What’s in the News?

·         Transposons influence the effects of genes and are called the tools of evolution, for their ability to rearrange the genome and introduce changes.

·         More than 45% of the human genome consists of transposable elements.

o    They create mutations in genes and lead to diseases. 

·         However, most of the transposons have themselves inherited mutations and have become inactive, and thus can’t move around within the gnome.

 

Jumping genes (Transposons)

·         The name of the jumping gene is IS110, which stands for Insertion Sequence, and such sequences are found in an array of life-forms, including bacteriophages, bacteria, plants, worms, fruit flies, mosquitos, mice, and humans.

They roam around the body, cutting and pasting themselves, repairing DNA and modifying it daily. 

 

Bridge RNA

·         Bridge RNA refers to a type of RNA (Ribonucleic Acid) molecule that plays a crucial role in the process of DNA rearrangement in certain organisms.

·         Bridge RNAs act as molecular bridges between different DNA segments during this intricate process of DNA rearrangement. 

Significance of Jumping genes:

·         The IS110 bridge recombination system expands the diversity of nucleic-acid-guided systems beyond CRISPR and RNA interference.

·         It offers a unified mechanism for the three fundamental DNA rearrangements — insertion, excision and inversion — that are required for genome design.

o    DNA insertion is a genetic process in which a segment of DNA is added to a different DNA segment, 

o    Excision is a mechanism in which a damaged DNA segment is removed, and 

o    Inversion is a method in which a piece of DNA in a chromosome gets reversed. 

·         With bridge RNA, researchers can program both the target and the donor sequence of DNA so they can mix and match any two that they want, whereas the guide RNA in CRISPR-Cas9 systems can specify only the target DNA sequence to be cut, not the one to be added in.