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The steps contributing to the production of primary transcripts involve a series of molecular interactions that initiate transcription of DNA within a cell's nucleus. Based on the needs of a given cell, certain DNA sequences are transcribed to produce a variety of RNA products to be translated into functional proteins for cellular use. To initiate the transcription process in a cell's nucleus, DNA double helices are unwound and [[hydrogen bond]]s connecting compatible nucleic acids of DNA are broken to produce two unconnected single DNA strands.<ref name="StrachanRead2004">{{cite book|author1=T. Strachan|author2=Andrew P. Read|title=Human Molecular Genetics 3|url=https://books.google.com/books?id=g4hC63UrPbUC|date=January 2004|publisher=Garland Science|isbn=978-0-8153-4184-0|pages=16–17}}</ref> One strand of the DNA template is used for transcription of the single-stranded primary transcript mRNA. This DNA strand is bound by an [[RNA polymerase]] at the [[promoter (genetics)|promoter]] region of the DNA.<ref name="Alberts3rd">{{cite web| vauthors = Alberts B |title=Molecular Biology of the Cell | edition = 3rd |url=https://www.ncbi.nlm.nih.gov/books/NBK28319/|work=NCBI|publisher=New York: Garland Science}}</ref>
[[File:Transcription.jpg|thumb|Transcription of DNA by RNA polymerase to produce primary transcript]]
In eukaryotes, three kinds of RNA—[[rRNA]], [[tRNA]], and mRNA—are produced based on the activity of three distinct RNA polymerases, whereas, in [[prokaryotes]], only one RNA polymerase exists to create all kinds of RNA molecules.<ref>{{cite web| vauthors = Griffiths AJ |title=An Introduction to Genetic Analysis |url= https://www.ncbi.nlm.nih.gov/books/NBK21853/|work=NCBI|publisher=New York: W.H. Freeman}}</ref> RNA polymerase II of eukaryotes transcribes the primary transcript, a transcript destined to be processed into mRNA, from the [[antisense]] DNA template in the 5' to 3' direction, and this newly synthesized primary transcript is complementary to the antisense strand of DNA.<ref name="StrachanRead2004" /> RNA polymerase II constructs the primary transcript using a set of four specific [[ribonucleoside]] monophosphate residues ([[
Studies of primary transcripts produced by RNA polymerase II reveal that an average primary transcript is 7,000 [[nucleotide]]s in length, with some growing as long as 20,000 nucleotides in length.<ref name="Alberts3rd"/> The inclusion of both [[exon]] and [[intron]] sequences within primary transcripts explains the size difference between larger primary transcripts and smaller, mature mRNA ready for translation into protein.
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===Processing===
The basic primary transcript modification process is similar for tRNA and rRNA in both eukaryotic and prokaryotic cells. On the other hand, primary transcript processing varies in mRNAs of prokaryotic and eukaryotic cells.<ref name="Cooper GM"/> For example, some prokaryotic bacterial mRNAs serve as templates for synthesis of proteins at the same time they are being produced via transcription. Alternatively, pre-mRNA of eukaryotic cells undergo a wide range of modifications prior to their transport from the nucleus to cytoplasm where their mature forms are translated.<ref name="Cooper GM"/> These modifications are responsible for the different types of encoded messages that lead to translation of various types of products. Furthermore, primary transcript processing provides a control for gene expression as well as a regulatory mechanism for the degradation rates of mRNAs. The processing of pre-mRNA in eukaryotic cells includes [[5' cap]]ping, [[polyadenylation|3'
===5' capping===
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