RNA Splicing: Definition, Steps, Types and Examples

Edited By Irshad Anwar | Updated on Jul 02, 2025 06:21 PM IST

What Is RNA Splicing?

RNA splicing is one of the basic processes involved in gene expression within eukaryotes, in which pre-messenger RNA is converted into mature messenger RNA. In simple terms, it entails the removal of non-coding sequences (introns) and joining the coding sequencing (exons). The splicing process ensures that only those sequences of nucleotides representing coding information are retained in the mRNA for translation into a given protein.

This Story also Contains

What Is RNA Splicing?
Types Of RNA Splicing
RNA Splicing Process
Regulation Of RNA Splicing
Treatment Strategies
RNA Splicing: A Critical Process

RNA Splicing: Definition, Steps, Types and Examples

This forms the central mechanism of the flow of genetic information from DNA to RNA to proteins, what is called the central dogma of molecular biology. The integrity of the genetic code itself is intrinsic to the process of RNA splicing, for this will allow for the proper assembly of amino acids into functional proteins. The process involves the precise excision of introns and the ligation of exons.

Types Of RNA Splicing

The different types of RNA splicing are:

Constitutive Splicing

Constitutive splicing is the earliest or most primitive form, wherein introns are removed uniformly and exons are joined back continuously. This type of splicing occurs in all cells and ensures that the genetic code is expressed correctly in the mRNA.

Alternative Splicing

Alternative splicing allows the generation of multiple protein variants from a single gene. It includes specific exons or excludes them for the formulation of different mRNA transcripts. Some major types of alternative splicing include:

Exon Skipping: The selective skipping of some exons is called exon skipping, resulting in alternative mRNA isoforms.

Intron Retention: During this process, some introns may be retained in the final mRNA and finally alter the function of the protein.

Mutually Exclusive Exons: Only one of the exons in a series is included in the mRNA.

Alternate 5' Splice Site: Multiple splice sites are available at the 5' end of an exon.

Alternate 3' Splice Site: Multiple splice sites are available at the 3' end of an exon.

Alternative splicing provides various means of increasing protein diversity so that one gene might offer its contribution towards several physiological processes and cellular functions.

RNA Splicing Process

The process of RNA splicing is a complicated, yet well-orchestrated read series of events in its molecular components. Key to this is the spliceosome, a huge RNA-protein complex including small nuclear RNAs and associated proteins. Small nuclear RNAs and associated proteins interact in concert within the spliceosome to effect the precise removal of introns and joining of exons in a series of steps:

Recognition Of Splice Sites:

The spliceosome recognises specific sequences at the boundaries between an intron and an exon.

Lariat Formation And Exon Ligation:

The intron loops into a lariat structure and then gets excised, while exons get ligated.

Release Of The Intron Lariat:

Release of the intron lariat and its degradation efficiency ensures that only the mature mRNA will be translated into protein.

Regulation Of RNA Splicing

RNA splicing is regulated by both cis-acting elements and transacting factors.

Cis-Acting Element

These are the splicing enhancers and silencers, either within the exons, known as the exonic splicing enhancers/silencers, or in the introns, called intronic splicing enhancers/ silencers. The effectiveness of this element regarding splice site selection is based on the splicing factors with which they bind.

Trans Acting Factors

These extend from factors of splicing and regulatory proteins that interact with spliceosome/RNA to regulate splicing events to the cellular environment itself and its involved cellular signalling pathways capable of modulating splicing. This thus enables the cell to adapt to a wide spectrum of physiological conditions and stressors.

RNA Splicing Errors And Diseases

It forms the basis for several genetic and acquired human diseases, as RNA splicing errors can be detrimental.

Mutations at splice sites or regulatory elements perturb normal splicing patterns and lead to aberrant mRNA and, consequently, dysfunctional protein.

For instance:

Spinal Muscular Atrophy: Caused by mutations in the SMN1 gene that affect the splicing of the SMN2 pre-mRNA.

Cystic Fibrosis: Splicing mistakes in the CFTR gene lead to aberrant splicing and reduce the chloride ion transport.

Treatment Strategies

Novel promising therapies targeting splicing mistakes. Gene therapy provides functional copies of the defective genes, whilst splice-switching oligonucleotides alter the splicing patterns and can be exploited as a therapy for splicing-related diseases.

RNA Splicing: A Critical Process

RNA splicing is carried out to generate the huge diversity of proteins required for innumerable functions within a living organism. This process confers on a cell the capacity to express different isoforms of proteins from one gene, therefore increasing functional genome diversity. Moreover, splicing regulation allows tissue-specific expression and adaptation to environmental changes; hence, it is crucial for development, cell differentiation, and cellular stress response.

Conclusion

RNA splicing is a universal, complex process, and its proper execution is required for appropriate gene expression and protein synthesis. Constitutive and alternative splicing mechanisms allow cells to generate an extremely diverse proteome from a relatively small number of genes. Indeed, the regulation of RNA splicing assures the right interpretations of the genetic information; splicing errors thus lead to serious diseases. Knowing the subtleties of RNA splicing opens up new avenues for therapeutic interventions and puts sense into the complexity of gene regulation.

Frequently Asked Questions (FAQs)

1. What is RNA splicing, and why is it so important?

Now, one of the ways this happens is through RNA splicing, an actual process of cutting out the noncoding regions from the pre-mRNA and then glueing the coding regions back together. This step in the processing of mRNA gives it maturation for the correct synthesis of protein; thus, proving genetic information properly on its way.

2. What is alternative splicing and protein diversity?

Alternative splicing therefore gives the option of more than one protein isoform from a single gene with selective inclusions or exclusions of different sets of exons. This confers increased functional potential onto the genome and facilitates the production of numerous proteins from the expression of a relatively small proportion of genes.

3. The spliceosome in RNA splicing?

The spliceosome is a nuclear complex of small nuclear RNAs and proteins implicated in the correct removal of introns and joining of exons from pre-mRNA. This is guaranteed by the recognition of splice sites, formation of lariat structures, and ligation of exons.

4. Which diseases are linked to errors in RNA splicing?

Some of the diseases caused by genetic, inherited, or spontaneous mutation in human genes include Spinal Muscular Atrophy, Cystic Fibrosis, and some cancers. Hence, such mistakes can lead to the generation of non-functional proteins associated with severe clinical phenotypes.

5. What are the experimental techniques to study RNA splicing

These methods include, amongst many others, RT-PCR and RNA sequencing for mechanisms and outcomes of RNA splicing studies, along with the splicing reporter assays. Many of these methods have already been used to investigate splicing patterns, search for splicing errors, and ask what regulatory elements and factors can mean.

6. What are the main steps involved in RNA splicing?

The main steps in RNA splicing are:

7. What is the spliceosome and what is its role in RNA splicing?

The spliceosome is a large complex of small nuclear ribonucleoproteins (snRNPs) and other proteins that catalyzes the splicing reaction. It recognizes splice sites, brings the exons together, and facilitates the removal of introns and joining of exons.

8. What are splice sites and how are they recognized?

Splice sites are specific sequences at the intron-exon boundaries that signal where splicing should occur. The 5' splice site (donor site) is typically GU, while the 3' splice site (acceptor site) is typically AG. These sites are recognized by components of the spliceosome, particularly the U1 and U2 snRNPs.

9. What is the branch point and what is its significance in RNA splicing?

The branch point is a conserved adenosine residue located near the 3' end of the intron. It's significant because it forms a branched structure (lariat) with the 5' end of the intron during splicing, which is crucial for the proper removal of the intron.

10. What is the difference between introns and exons?

Introns are non-coding sequences within a gene that are removed during RNA splicing, while exons are coding sequences that remain in the mature mRNA and are translated into proteins. Introns are "intervening sequences," while exons are "expressed sequences."

11. How does RNA splicing contribute to genetic diversity?

RNA splicing contributes to genetic diversity through alternative splicing, where different combinations of exons can be joined together from the same pre-mRNA. This allows a single gene to produce multiple protein variants, increasing the functional diversity of the proteome without increasing the number of genes.

12. How does RNA editing relate to RNA splicing?

While RNA splicing involves the removal of introns and joining of exons, RNA editing refers to molecular processes that alter the nucleotide sequence of an RNA molecule after transcription. Both processes contribute to increasing the diversity of gene products, but they occur through different mechanisms and at different stages of RNA processing.

13. How does splicing contribute to nonsense-mediated decay (NMD)?

Splicing can contribute to nonsense-mediated decay by:

14. What is the significance of the conserved GU-AG rule in splicing?

The GU-AG rule refers to the highly conserved dinucleotides at the 5' (GU) and 3' (AG) ends of introns. These sequences are crucial for:

15. How does alternative splicing occur?

Alternative splicing occurs when different combinations of exons are selected for inclusion in the mature mRNA. This can happen through various mechanisms, such as exon skipping, intron retention, alternative 5' or 3' splice site selection, or mutually exclusive exons.

16. How does the cell ensure the accuracy of RNA splicing?

The cell ensures splicing accuracy through several mechanisms:

17. What is exon definition and how does it differ from intron definition?

Exon definition is a model of splice site recognition where the splicing machinery first identifies exons and then connects them. This is common in organisms with small exons and large introns. Intron definition, more common in organisms with small introns, involves the direct recognition of introns for removal. The choice between these models can affect splicing efficiency and alternative splicing patterns.

18. How do splicing enhancers and silencers regulate alternative splicing?

Splicing enhancers and silencers are regulatory sequences that can promote or inhibit the use of nearby splice sites. Enhancers bind proteins that promote spliceosome assembly, while silencers bind proteins that interfere with spliceosome assembly. These elements allow for fine-tuning of splice site selection and contribute to tissue-specific or developmental stage-specific alternative splicing patterns.

19. What is the significance of the polypyrimidine tract in RNA splicing?

The polypyrimidine tract is a sequence rich in pyrimidine nucleotides (C and U) located upstream of the 3' splice site. It plays a crucial role in splice site recognition and spliceosome assembly by providing a binding site for splicing factors, particularly U2AF65, which helps recruit the U2 snRNP to the branch point.

20. What are the consequences of errors in RNA splicing?

Errors in RNA splicing can lead to the production of non-functional or altered proteins, which may result in genetic disorders or diseases. Splicing errors can cause frame shifts, premature stop codons, or the inclusion of non-coding sequences in the final protein product.

21. What is the relationship between DNA mutations and splicing defects?

DNA mutations can lead to splicing defects in several ways:

22. How do viruses exploit or manipulate host cell splicing machinery?

Viruses interact with host cell splicing in various ways:

23. What is the role of circular RNAs in relation to splicing?

Circular RNAs (circRNAs) are related to splicing in several ways:

24. How does the speed of transcription affect splicing?

The speed of transcription can affect splicing by:

25. What is the difference between cis-splicing and trans-splicing?

Cis-splicing is the conventional form of splicing where introns are removed and exons are joined within a single pre-mRNA molecule. Trans-splicing, on the other hand, involves the joining of exons from two different pre-mRNA molecules. Trans-splicing is less common but occurs in some organisms like trypanosomes and nematodes.

26. What is intron retention and how does it differ from other forms of alternative splicing?

Intron retention is a form of alternative splicing where an intron is kept in the mature mRNA. Unlike other forms of alternative splicing (such as exon skipping or alternative splice site selection), intron retention results in the inclusion of sequences that are typically removed. This can lead to the introduction of premature stop codons or alter the reading frame, often resulting in nonsense-mediated decay of the transcript.

27. How does self-splicing differ from spliceosome-mediated splicing?

Self-splicing is a process where some introns can catalyze their own removal without the need for external enzymes or the spliceosome. This occurs in certain RNA molecules, such as Group I and Group II introns. Spliceosome-mediated splicing, on the other hand, requires the complex machinery of the spliceosome to remove introns from pre-mRNA.

28. What is recursive splicing and why is it important?

Recursive splicing is a process where very long introns are removed in multiple steps, rather than in a single splicing event. It's important because:

29. How do splicing patterns differ between plants and animals?

Splicing patterns in plants and animals differ in several ways:

30. What is RNA splicing and why is it important?

RNA splicing is the process of removing non-coding sequences (introns) from pre-mRNA and joining the coding sequences (exons) to form mature mRNA. It's important because it allows for the production of multiple protein variants from a single gene, increases genetic diversity, and ensures that only the necessary genetic information is translated into proteins.

31. What is the role of small nuclear RNAs (snRNAs) in splicing?

Small nuclear RNAs (snRNAs) are essential components of the spliceosome. They help in recognizing splice sites, aligning the exons, and catalyzing the splicing reaction. The most important snRNAs in splicing are U1, U2, U4, U5, and U6.

32. How does the secondary structure of pre-mRNA affect splicing?

The secondary structure of pre-mRNA can significantly impact splicing by:

33. What is the role of RNA helicases in splicing?

RNA helicases play crucial roles in splicing by:

34. How does co-transcriptional splicing differ from post-transcriptional splicing?

Co-transcriptional splicing occurs while the RNA is still being synthesized by RNA polymerase II, while post-transcriptional splicing happens after transcription is complete. Co-transcriptional splicing:

35. What is the role of SR proteins in splicing?

SR (Serine/Arginine-rich) proteins are important splicing factors that:

36. How do splicing factors recognize and bind to their target sequences?

Splicing factors recognize and bind to their target sequences through:

37. What is the role of ATP in the splicing process?

ATP plays several crucial roles in the splicing process:

38. How do minor introns differ from major introns in their splicing mechanism?

Minor introns, also known as U12-type introns, differ from major (U2-type) introns in several ways:

39. What is the role of the Prp8 protein in splicing?

Prp8 is a large, highly conserved protein that plays a central role in splicing:

40. How do splicing patterns change during development and differentiation?

Splicing patterns can change dramatically during development and differentiation due to:

41. How does the concept of splice site strength influence splicing outcomes?

Splice site strength refers to how well a splice site matches the consensus sequence and how efficiently it's recognized by the spliceosome. It influences splicing outcomes by:

42. What is the significance of branch point selection in splicing?

Branch point selection is crucial in splicing because:

43. How do splicing patterns differ between constitutive and alternative exons?

Constitutive exons (always included) and alternative exons (sometimes included) differ in several ways: