Yes, exons are not removed during the process of splicing in gene expression. Instead, introns are removed and exons are joined together to form the mature mRNA molecule.
Exons are the parts of a gene that are kept and expressed, while introns are the parts that are removed during the process of splicing.
Exons are the parts of the mRNA that are kept and introns are the parts that are removed during the process of mRNA splicing.
Yes, introns are transcribed along with exons during the process of gene expression, but they are later removed from the mRNA through a process called splicing before the final mRNA is translated into a protein.
Introns are non-coding sections of DNA that are removed during the process of gene expression. They help regulate gene expression and can also contribute to genetic diversity through alternative splicing.
No, splicing does not occur during transcription. Splicing is a process that happens after transcription, where non-coding regions of the RNA molecule are removed and the coding regions are joined together to form the final mRNA molecule.
Exons are the parts of a gene that are kept and expressed, while introns are the parts that are removed during the process of splicing.
Exons are the parts of the mRNA that are kept and introns are the parts that are removed during the process of mRNA splicing.
Yes, introns are transcribed along with exons during the process of gene expression, but they are later removed from the mRNA through a process called splicing before the final mRNA is translated into a protein.
Introns are non-coding sections of DNA that are removed during the process of gene expression. They help regulate gene expression and can also contribute to genetic diversity through alternative splicing.
No, splicing does not occur during transcription. Splicing is a process that happens after transcription, where non-coding regions of the RNA molecule are removed and the coding regions are joined together to form the final mRNA molecule.
During the process of splicing in eukaryotic mRNA, introns are removed. This leaves only the exons, which are the coding regions, to be joined together to form the final mRNA molecule that will be translated into a protein.
During gene expression, splice sites are recognized by specific sequences in the pre-mRNA called splice sites. These sequences signal the splicing machinery to cut out introns and join together exons to form the mature mRNA. Proteins called spliceosomes bind to the splice sites and facilitate the splicing process.
Before the RNA leaves the nucleus, the introns are removed and the exons are joined together, producing an mRNA molecule with a continuous coding sequence. This process is called RNA splicing.
Introns are non-coding sections of DNA that are removed during the process of gene expression in eukaryotes. They do not code for proteins but play a crucial role in regulating gene expression by affecting how the coding regions (exons) are spliced together. This process, known as alternative splicing, allows a single gene to produce multiple protein variants, increasing the diversity of proteins that can be produced from a single gene.
Yes, exons can be spliced out during the process of gene expression through a mechanism called alternative splicing. This process allows different combinations of exons to be included or excluded from the final mRNA transcript, resulting in the production of multiple protein isoforms from a single gene.
During the process of RNA splicing, introns are spliced out, while exons are joined together to form the mature mRNA molecule.
The definition of the 'intron' is part of the DNA sequence within a gene. It is the sequence within a particular gene that is removed during the RNA splicing process.