Analytical Profile of Coleus Forskohlii | Forskolin .pptx
Transcription
1. Transcription
When a protein is needed by a cell, the genetic code for that protein
must be read from the DNA and processed.
A two step process:
1. Transcription = synthesis of a single-stranded RNA molecule
using the DNA template (1 strand of DNA is transcribed).
2. Translation = conversion of a messenger RNA sequence into the
amino acid sequence of a polypeptide (i.e., protein synthesis)
Both processes occur throughout the cell cycle. Transcription
occurs in the nucleus, whereas translation occurs in the
cytoplasm.
2. Five different types of RNA, each encoded by different genes:
1. mRNA Messenger RNA, encodes the amino acid sequence of
a polypeptide.
2. tRNA Transfer RNA, transports amino acids to ribosomes
during translation.
3. rRNA Ribosomal RNA, forms complexes called ribosomes
with protein, the structure on which mRNA is
translated.
4. snRNA
5. miRNA/siRNA
Small nuclear RNA, forms complexes with proteins
used in eukaryotic RNA processing (e.g., exon
splicing and intron removal).
Micro RNA/small interfering RNA, short ~22 nt RNA
sequences that bind to 3’ UTR target mRNAs and
result in gene silencing.
3. Transcription: How is an RNA strand synthesized?
1. Regulated by gene regulatory elements within each gene.
2. DNA unwinds next to a gene.
3. RNA is transcribed 5’ to 3’ from the template (3’ to 5’).
4. Similar to DNA synthesis, except:
NTPs instead of dNTPs (no deoxy-)
No primer
No proofreading
Adds Uracil (U) instead of thymine (T)
RNA polymerase
5. Three Steps to Transcription:
1. Initiation
2. Elongation
3. Termination
Occur in both prokaryotes and eukaryotes.
Elongation is conserved in prokaryotes and eukaryotes.
Initiation and termination proceed differently.
6. Step 1-Initiation, E. coli model:
Fig. 5.3
Each gene has three regions:
1. 5’ Promoter, attracts RNA polymerase
-10 bp 5’-TATAAT-3’
-35 bp 5’-TTGACA-3’
2. Transcribed sequence (transcript) or RNA coding sequence
3. 3’ Terminator, signals the stop point
7. Step 1-Initiation, E. coli model:
1. RNA polymerase combines with sigma factor (a polypeptide) to
create RNA polymerase holoenzyme
Recognizes promoters and initiates transcription.
Sigma factor required for efficient binding and transcription.
Different sigma factors recognize different promoter
sequences.
2. RNA polymerase holoenzyme binds promoters and untwists DNA
Binds loosely to the -35 promoter (DNA is d.s.)
Binds tightly to the -10 promoter and untwists
3. Different types and levels of sigma factors influence the level and
dynamics of gene expression (how much and efficiency).
9. Step 2-Elongation, E. coli model:
1. After 8-9 bp of RNA synthesis occurs, sigma factor is released and
recycled for other reactions.
2. RNA polymerase completes the transcription at 30-50 bp/second.
3. DNA untwists rapidly, and re-anneals behind the enzyme.
4. Part of the new RNA strand is hybrid DNA-RNA, but most RNA is
displaced as the helix reforms.
11. Step 3-Termination, E. coli model:
Two types of terminator sequences occur in prokaryotes:
1. Type I (-independent)
Palindromic, inverse repeat forms a hairpin loop and is believed
to physically destabilize the DNA-RNA hybrid.
2. Type II (-dependent)
Involves factor proteins, believed to break the hydrogen bonds
between the template DNA and RNA.
Fig. 5.5
12. Prokaryotes possess only one type of RNA polymerase
transcribes mRNAs, tRNAs, and rRNAs
Transcription is more complicated in eukaryotes
Eukaryotes possess three RNA polymerases:
1. RNA polymerase I, transcribes three major rRNAs 12S, 18S, 5.8S
2. RNA polymerase II, transcribes mRNAs and some snRNAs
3. RNA polymerase III, transcribes tRNAs, 5S rRNA, and snRNAs
13. Transcription of protein-coding genes by RNA polymerase II
RNA polymerase II transcribes a precursor-mRNA
We can divide eukaryotes promoter into two regions:
1. The core promoters elements. The best characterized are
A short sequence called Inr (Initiator)
TATA Box = TATAAAA, located at about position -30
*AT-rich DNA is easier to denature than GC-rich DNA
2. Promoter proximal elements (located upstream, ~-50 to -
200 bp)
“Cat Box” = CAAT and “GC Box” GGGCGG
Different combinations occur near different genes.
Transcription regulatory proteins (activators) and enhancers also
are required.
14. Transcription regulatory proteins = Activators
High-level transcription is induced by binding of activator
factors to DNA sequences called enhancers.
Enhancers are usually located upstream of the gene they
control, they modulate transcription from a distance.
Can be several kb from the gene
Silencer elements and repressor factors also exist
15. Transcription of protein-coding genes by RNA polymerase II
General Transcription factors (GTFs) also are required by RNA
polymerases (function is similar to sigma factor).
GTFs are proteins, assembled on the core promoter
Each GTF works with only one kind of RNA polymerase (required
by all 3 RNA polymerases).
Numbered (i.e., named) to match their RNA polymerase.
TFIID, TFIIB, TFIIF, TFIIE, TFIIH
Binding of GTFs and RNA polymerase occurs in a set order in
protein coding genes.
Complete complex (RNA polymerase + GTFs) is called a pre-
initiation complex (PIC).
16. Order of binding is: IID + IIA + IIB + RNA poly. II + IIF +IIE +IIH
Fig. 5.7.
17. Production of the mRNA molecule (Fig. 5.8)
Three main parts:
1. 5’ untranslated region (5’ UTR) or leader sequence
2. Coding sequence, specifies amino acids to be translated
3. 3’ untranslated region ( 3’ UTR) or trailer sequence
may contain information that signals the stability of the
particular mRNA
18. mRNA differences between prokaryotes and eukaryotes:
Prokaryotes
1. mRNA transcript is mature, and used directly for translation
without modification.
2. Since prokaryotes lack a nucleus, mRNA also is translated on
ribosomes before it is transcribed completely (i.e., transcription
and translation are coupled).
3. Prokaryote mRNAs are polycistronic, they contain amino acid
coding information for more than one gene.
Eukaryotes
1. mRNA transcript is not mature (pre-mRNA); must be processed.
2. Transcription and translation are not coupled (mRNA must first
be exported to the cytoplasm before translation occurs).
3. Eukaryote mRNAs are monocistronic, they contain amino acid
sequences for just one gene.
22. Promoters
• A promoter is a region of DNA where transcription of a
gene initiates. Promoters are adjacent and typically
upstream (5’) of the sense strand of the regulated gene.
• Promoters are a vital component of expression vectors
because they control the attachment of RNA polymerase
to DNA and are directly responsible for the amount of
transcript generated.
23. The promoter region controls when and where the RNA
polymerase will attach to DNA so transcription can commence.
Promoter binding is very different in bacteria compared to
eukaryotes.
In bacteria, RNA polymerase only requires the associated
protein sigma factor to bind the promoter.
On the other hand, the process in eukaryotes is much more
complex. Eukaryotes require a minimum of seven
transcription factors in order for the binding of RNA
polymerase II (eukaryote-specific RNA polymerase) to the
promoter.
24. • There are three main portions that make up a promoter: core
promoter, proximal promoter, and distal promoter.
• The core promoter region is located most proximally and
contains the RNA polymerase binding site, TATA box, and
transcription start site (TSS).
• RNA polymerase will bind to this core promoter region stably
and transcription of the template strand can initiate.
25. • The TATA box is a DNA sequence (5'-TATAAA-3) within the
core promoter region where general transcription factor proteins
and histones can bind.
• Histone binding will prevent the initiation of transcription
whereas transcription factors will drive the onset of
transcription.
• The most 3' portion of the core promoter is the TSS which is
where transcription literally is initiated.
26. • However, only eukaryotes and archaea
contain this TATA box.
• Prokaryotes contain something called the
Pribnow box which usually consists of the
six nucleotides TATAAT.
27. • Promoters in prokaryotic organisms are two short DNA
sequences located at the -10 (10bp 5' or upstream) and -35
positions from the transcription start site (TSS).
• Their equivalent to the eukaryotic TATA box, the Pribnow
box (TATAAT) is located at the -10 position and is essential for
transcription initiation.
• The -35 position, simply titled the -35 element, typically consists
of the sequence TTGACA and this element controls the rate of
transcription.
28. Production of mature mRNA in eukaryotes:
1. 5’ cap
After 20-30 nucleotides have been synthesized, the 5’-end of
the mRNA is capped 5’ to 5’ with a guanine nucleotide (See
Fig. 5.10).
Results in the addition of two methyl (CH3) groups.
Essential for the ribosome to bind to the 5’ end of the mRNA.
2. Poly (A) tail
50-250 adenine nucleotides are added to 3’ end of mRNA.
Complex enzymatic reaction.
Stabilizes the mRNA, and plays an important role in
transcription termination.
3. Introns (non-coding sequences between exons) are removed and
exons (amino acid coding sequences) are spliced.
29. Introns and exons:
Eukaryote pre-mRNAs often have intervening introns that must be
removed during RNA processing (as do some viruses).
intron = intragenic region made of non-coding DNA sequences
between exons in a gene.
exon = expressed DNA sequences in a gene, code for amino acids.
1993: Richard Roberts (New England Biolabs) & Phillip Sharp (MIT)
Fig. 5.12
30. mRNA splicing of exons and removal of introns:
1. Introns typically begin with a 5’-GU and end with AG-3’.
2. Cleavage occurs first at the 5’ end of intron 1 (between 2 exons).
3. The now free G joins with an A at a specific branch point sequence
in the middle of the intron, using a 2’ to 5’ phosphodiester bond.
Intron forms a lariat-shaped structure.
4. Lariat is excised, and the exons are joined to form a spliced mRNA.
5. Splicing is mediated by splicosomes, complexes of small nuclear
RNAs (snRNAs) and proteins, that cleave the intron at the 3’ end
and join the exons.
6. Introns are degraded by the cell.
33. 1. Synthesis of ribosomal RNA and ribosomes (continued):
7. Transcription occurs by the same mechanism as protein-coding
genes, but generally using RNA polymerase I.
8. rRNA synthesis requires its own array of specific transcription
factors (TFs)
9. Coding sequences for RNA subunits within rDNA genes contain
the following:
internal transcribed spacer ITS
external transcribed spacer ETS
nontranscribed spacer NTS
10. ITS units (analogous to introns) separate the RNA subunits
through the pre-rRNA stage, whereupon ITS & ETS are cleaved
out and rRNAs are assembled.
11. Subunits of mature ribosomes are bonded together by H-bonds.
12. Finally, transported to the cytoplasm to initiate protein synthesis.
37. 2. Synthesis of tRNA:
1. tRNA genes also occur in repeated copies throughout the genome,
and may contain introns.
2. Each tRNA (75-90 nt in length) has a different sequence that
binds a different amino acid.
3. Many tRNAs undergo extensive post-transcription modification,
especially those in the mitochondria and chloroplast.
4. tRNAs form clover-leaf structures, with complementary base-
pairing between regions to form four stems and loops.
5. Loop #2 contains the anti-codon, which recognizes
mRNA codons during translation.
6. Same general mechanism using RNA polymerase III, promoters,
unique TFs, plus post-transcriptional modification from pre-tRNA.
39. 3. Synthesis of snRNA (small nuclear RNA):
• Form complexes with proteins used in eukaryotic RNA processing,
such as splicing of mRNA after introns are removed.
• Transcribed using RNA polymerase II or III.
• Associated with small nuclear ribonucleoproteins (snRNPs).
• Also function in regulation of transcription factors and
maintenance of telomeres.
U7 H/ACA