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Introduction
What is RNA?
RNA, or ribonucleic acid, is a fundamental biomolecule that plays a central role in various biological processes, including protein synthesis, gene regulation, and cellular communication. Structurally, RNA is like DNA but has key differences: it is typically single-stranded, contains the sugar ribose (instead of deoxyribose), and contains uracil (U) in place of thymine (T). These differences allow RNA to perform dynamic functions within the cell.
RNA exists in several forms, each tailored for specific tasks. Messenger RNA (mRNA) carries genetic information from DNA to ribosomes for protein synthesis. Transfer RNA (tRNA) acts as a molecular adaptor, delivering amino acids during translation, while ribosomal RNA (rRNA) forms the ribosome's structural and functional core. Beyond these, noncoding RNAs (ncRNAs), such as microRNAs (miRNAs) and long noncoding RNAs (lncRNAs), regulate gene expression, shape chromatin structure, and even participate in cellular defense mechanisms. RNA also demonstrates enzymatic activity, as in ribozymes, catalyzing chemical reactions. Additionally, RNA is pivotal in processes like RNA interference (RNAi), which silences the expression of specific genes and has fueled innovations in biotechnology, including CRISPR genome editing tools (1) and RNA-based vaccines (2).
Ava: Dr. Rivera, I’ve been struggling with RNA extractions in the lab. No matter how careful I am, something always seems to go wrong. Do you have any advice?
Dr. Rivera: You’re not alone, Ava. RNA extraction can be tricky, especially with RNA being prone to degradation. But with the proper techniques and tools, you can make it almost foolproof.
Ava: That’s exactly what I need to hear! But I feel overwhelmed; there are so many steps and variables. How do I know I’m doing it right?
Dr. Rivera: Start by understanding the science behind each step. Then, learn the best practices for handling and storing your samples and how you can optimize yields for different tissues. Come and let’s level up your skills!
RNA structure
RNA is a single-stranded molecule made up of smaller building blocks called nucleotides. Each nucleotide contains:
- Nitrogenous base: Adenine (A), uracil (U), cytosine (C), and guanine (G). RNA uses uracil instead of thymine (T), which is found in DNA.
- Ribose sugar: This five-carbon sugar (also called pentose) includes an additional hydroxyl (-OH) group compared to the deoxyribose in DNA.
- Phosphate group: This forms the backbone of the RNA strand, linking the nucleotides together.
The single-stranded structure of RNA allows it to fold into diverse three-dimensional shapes necessary for its various functions.
A diagram showing the structural differences between RNA and DNA (top), including the nucleobases that comprise them (bottom). Key difference: RNA vs DNA
RNA and DNA are considered nucleic acids, a group of biomolecules that store and transmit genetic information. However, the two differ in structure and function. RNA is typically single-stranded, while DNA is double-stranded, forming a double helix. RNA contains a ribose sugar, whereas DNA uses deoxyribose, which lacks one oxygen atom. Additionally, RNA replaces thymine (T) with uracil (U) as a nitrogenous base. Functionally, RNA is more versatile, acting as a messenger, adapter, catalyst, and regulator, while DNA primarily serves as a stable, long-term storage of genetic information.
RNA is also more transient and dynamic, often operating within the cytoplasm and nucleus to facilitate immediate cellular processes like protein synthesis or gene regulation. RNA is also found in different subcellular compartments. In contrast, DNA (particularly genomic DNA) resides in the nucleus (or nucleoid in prokaryotes) and is tightly packed to protect its integrity.
How RNA is made: Understanding transcription
RNA is synthesized through a process called transcription, which occurs in three steps:
- Initiation: Transcription begins when the enzyme RNA polymerase binds to a specific region of the DNA called the promoter. This region signals the starting point for RNA synthesis. Next, RNA polymerase unwinds the DNA double helix to expose the template strand, which will be used to synthesize the RNA molecule.
- Elongation: During elongation, RNA polymerase moves along the DNA template strand, adding complementary RNA nucleotides to the growing RNA chain. The RNA sequence is complementary to the DNA template strand, except that uracil (U) replaces thymine (T).
- Termination: Transcription continues until RNA polymerase encounters a termination signal in the DNA sequence. This signal indicates the end of the RNA transcript. Upon reaching this signal, RNA polymerase releases the newly synthesized RNA molecule and detaches it from the DNA.
RNA molecules are usually single-stranded because only one of the DNA strands is used as a template for transcription.
A diagram showing the transcription process, in which RNA is synthesized from the DNA template strand by RNA polymerase. (1) RNA polymerase binds to the promoter region on the DNA molecule, (2) RNA is made as the RNA polymerase transcribes the template DNA, and (3) RNA polymerase dissociates from the DNA, releasing the newly synthesized RNA. Different types of RNA
The single-stranded structure of RNA enables it to perform diverse functions. It serves as a template for protein synthesis, folds into complex three-dimensional shapes to interact with other molecules, and binds to complementary RNA sequences (e.g., miRNA) to regulate gene expression. Below is a table that summarizes the functions of different types of RNA, including their roles in the cell.
Different types of RNA and their roles.
Function | Type | Role | Structure/Shape |
|---|---|---|---|
| Protein synthesis (also called translation) | Messenger RNA (mRNA) | Carries the genetic information from DNA in the form of a codon (sequence of three consecutive nucleotides), specifying a particular amino acid for protein synthesis at the ribosomes. | A single-stranded molecule that is often linear. |
| Transfer RNA (tRNA) | Adapter for protein synthesis, matching specific amino acids to codons during translation. | Cloverleaf structure with three hairpin loops. Its anticodon loop pairs with the mRNA codon. | |
| Ribosomal RNA (rRNA) | Structural and catalytic component of ribosomes, facilitating peptide bond formation and aligning tRNA with mRNA during translation. | Complex 3D structure forming part of ribosome subunits (large and small). | |
| RNA interference (RNAi)/Gene silencing | MicroRNA (miRNA) | Silences genes by binding to the 3’ UTR (untranslated region) of the target mRNA, leading to translation repression or mRNA degradation. | Short single-stranded RNA (~22 nucleotides), often folded in a hairpin structure before processing. |
| Small interfering RNA (siRNA) | Suppresses the expression of specific genes by binding to complementary sequences inside the coding region of mRNA, inducing cleavage and preventing translation. | Short double-stranded RNA (~20–25 base pairs), but becomes linear and unwound when bound to the RISC complex (RNA–induced silencing complex). | |
| Piwi-interacting RNA (piRNA) | Maintains genome integrity in germ cells by silencing transposons (genetic elements that can transpose from one location to another within a genome) and regulating gene expression. | Single-stranded, typically longer than miRNA (~24–30 nucleotides), with no specific secondary structure. | |
| Gene regulation | Long non-coding RNA (lncRNA) | Regulates gene expression at multiple levels, including epigenetic regulation, post-transcriptional regulation, transcription, alternative splicing and nuclear import. | Long single-stranded RNA (non-protein coding) >200 nucleotides in length, often folded into complex secondary structures. |
| Intracellular signaling | Circulating cell-free RNA (ccfRNA) | Often released from dying cells, offering non-invasive biomarkers for disease states (e.g., cell-free miRNA in cancer detection) and cell-cell communication via RNA-mediated signaling. | Extracellular RNA that is typically single-stranded and stabilized by protein complexes or vesicles such as Ago2. |
| Exosomal RNA (exRNA)* | Naturally occurring secretory vesicles loaded with RNA molecules that often indicate changes in cellular signaling and disease states (e.g., neurodegeneration, tumor metastasis). | Packaged in extracellular vesicles (EVs) with a diverse range of RNA types (e.g., mRNA, miRNA). | |
| RNA maturation and stability | Small nuclear RNA (snRNA) | Participates in mRNA processing and facilitates splicing by removing introns from pre-mRNA through its association with the spliceosome. | Small, single-stranded RNA (~150 nucleotides) forming part of snRNP (small nuclear ribonucleoproteins) complexes within the spliceosome. |
| Small nucleolar RNA (snoRNA) | Guides chemical modification of other RNAs, directing methylation and pseudouridylation of rRNA, tRNA, and snRNA. | Small single-stranded RNA, often found in dense nuclear bodies called nucleoli. The box C/D and box H/ACA snoRNAs are the most abundant classes. | |
| Ribonuclease P RNA (RNase P RNA) | RNA component of the ribozyme (an RNA enzyme) that cleaves precursor tRNA to generate mature tRNA. | Single-stranded RNA that forms part of an RNA–protein complex with catalytic activity. | |
| Y RNA | Ensures RNA stability and participates in initiating DNA replication. It is also implicated in tumor proliferation. | Short, single-stranded RNA (~100 nucleotides) forming part of the Ro ribonucleoprotein complex. | |
| Protein translocation | Signal recognition particle RNA (7SL RNA or SRP RNA) | Directs nascent proteins to the endoplasmic reticulum for secretion or membrane insertion. | Single-stranded RNA, folded into a specific structure to interact with ribosomes and proteins. |
| Telomere synthesis | Telomerase RNA | Serves as a template for adding telomere repeats, preventing DNA loss during replication. | Single-stranded RNA with a specific template sequence for telomere synthesis that folded into a complex. |
* The term exosome is now preferentially referred to as extracellular vesicles (EVs). Therefore, evRNA is adapted more frequently than exRNA.
Subcellular locations and RNA roles
RNA molecules are distributed across various subcellular compartments, where their location dictates their function and relevance in biological processes, including their biomedical applications. Determining the spatial location of RNA, its distribution within the cell, and the dynamic change in their location helps researchers better understand the regulation of cellular processes, gene expression, and disease mechanisms.
It also enables the identification of different types of RNA that are crucial for specific biological functions and guides the development of targeted therapies for various diseases. This knowledge is critical for optimizing RNA extraction methods, as different RNA populations require tailored protocols to ensure integrity and accurate analysis for both basic research and clinical applications.
In most research applications, such as gene expression analysis, total RNA isolates that do not discriminate between subcellular locations are sufficient. However, for other applications, such as when studying the functions of mitochondrial RNA, isolating RNA for structural elucidations, or characterizing the functions of organelle-specific RNAs (e.g., snoRNAs), several considerations for extracting RNA should be noted for optimal recovery.
Subcellular locations of the different types of RNA, their roles, extraction considerations, and research applications.
Subcellular location | Role | Extraction considerations | Applications |
|---|---|---|---|
| Cytoplasm | |||
| Nucleus | |||
| Nucleolus | |||
| Extracellular (Exosomal) | |||
| Mitochondria | |||
| Germline |
Applications of RNA in research
RNA is involved in a wide array of cellular processes that are crucial to the proper functioning of an organism. As we have seen, RNA exists in different forms, each with distinct functions and localized to specific subcellular compartments. The dynamic roles and distributions of RNA make them a valuable tool for researchers who are aiming to explore and manipulate genetic information.
- RNA biomarker research – one of the most prominent research applications of RNA is in the study of diseases. RNA’s involvement in regulating gene expression means that alterations in RNA molecules can have profound implications for various diseases, including cancer, genetic disorders, and neurodegenerative diseases. For example, in cancer research, RNA can reveal how tumors evade the immune system or resist treatment, providing relevant data on how to develop more effective therapies.
- Biotechnology – one of the most notable applications of RNA research is in the development of RNA vaccines, such as the COVID-19 mRNA vaccines, which have demonstrated the potential of RNA to trigger immune responses and combat infectious diseases. Beyond vaccines, RNA is being explored as a therapeutic tool to treat a wide range of conditions, including viral infections, genetic disorders, and even some cancers.
- Pathology – the presence and patterns of RNA expression provide crucial information about the health status of an individual. Through techniques like RNA sequencing (RNA-seq), scientists can analyze gene expression profiles and detect abnormalities that may indicate disease or other health conditions.
- Environmental and agricultural research – RNA studies in plants, for example, help researchers understand how plants respond to environmental stressors, such as drought or disease, and how they can be engineered for improved resilience or yield. In animal research, RNA studies help scientists explore genetic traits, disease susceptibility, and the effects of environmental factors on gene expression.