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微生物遺傳與生物技術 (Microbial Genetics and Biotechnology)

微生物遺傳與生物技術 (Microbial Genetics and Biotechnology). 金門大學 食品科學系 何國傑 教授. Bacterial gene expression and its regulation. Gene: DNA region that carry the information for synthesis of RNA or RNA and protein. 2. Codon: each 3 nucleotides on DNA or RNA.

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微生物遺傳與生物技術 (Microbial Genetics and Biotechnology)

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  1. 微生物遺傳與生物技術(Microbial Genetics and Biotechnology) 金門大學 食品科學系 何國傑 教授

  2. Bacterial gene expression and its regulation

  3. Gene: DNA region that carry the information for synthesis of • RNA or RNA and protein. • 2. Codon: each 3 nucleotides on DNA or RNA. • 3. Genetic code: The assignment of each of the possible codons • to amino acids. • 4. The first step in gene expression is to transcribe (or copy) an • RNA from one strand of DNA. • 5. Types of RNA: There are many different types of RNA in cells. • The major three type are mRNA (messenger RNA), rRNA • (ribosomal RNA) and tRNA (transfer RNA). • (1) mRNA – The RNA carries the gene’s messenger (or • information) for protein. • (2) rRNA – RNA component of a ribosome. • (3) tRNA – The RNA carries an amino acid to a codon on mRNA. I. Terminology

  4. II. Structure of RNA • RNA is similar to DNA in that it is composed of a chain of • nucleotides • Nucleotides of RNA contain the sugar ribose instead of • deoxyribose. The second carbon of ribose is attached to a • hydroxyl group rather than hydrogen in deoxyribose. • 3. RNA has uracil instead of thymine found in DNA. • RNA is usually single stranded. However, a secondary • structure can form by pairing between the bases in some • regions of molecule may cause it to fold up on itself to form • double-stranded region. • The rule for double-stranded RNA is slightly different from • pairing rule for DNA. In RNA G can pair with U as well as C. • GU does not share hydrogen bond, it does not contribute to • the stability of the double-stranded RNA.

  5. II. Structure of RNA

  6. II. Structure of RNA 6. RNA can form tertiary structure when the unpaired region in a hairpin pairs with another region of the same RNA molecule to form a knot, a pseudoknot. 7. RNA processing and modification (1) In RNA processing, the covalent bonds can be broken and the smaller pieces of RNA can be religated into new recombination. One of the most extreme cases of RNA processing, called RNA editing, the nucleotides can be excised or added to mRNA after it has been from DNA. (2) RNA modification involved altering the bases or sugar of RNA. For example, the methylation of bases and sugars.

  7. II. Structure of RNA

  8. II. Structure of RNA Ψ: pseudouracil

  9. III. Transcription • The synthesis of RNA on DNA template and is work of RNA polymerase • In eukaryotic cells, there are three kinds of RNA polymerases: RNA polymerase I for rRNA synthesis; RNA polymerase II for mRNA synthesis; RNA polymerase III for tRNA synthesis. In prokaryotic cells such as bacteria, there is only one kind of RNA polymerase for all three type of RNA synthesis, exception that the RNA synthesis of the primer for Okazaki fragment. • E. coli RNA polymerase consists of six subunits: two identical α, one β, one β’, one small ω and σ factor. 3. α and β subunits are essential parts of RNA polymerase; ω helps the assembly of RNA polymerase and σ factor is required for initiation and cycles of the enzyme after initiation of transcription. RNA polymerase without σ factor is called core enzyme, and with it is called holoenzyme.

  10. III. Transcription • One of σdomain, σ2 contacts β’ subunit and is in position to bind to the -10 • region of the promoter. • Another two domains, σ3 and σ4 contact the β subunit further upstream in the • active-center channel in such a way that domain σ4 in position to contact the -35 • region of promoter. • *β and β’ form pincers of crab claw

  11. III. Transcription • Much like DNA polymerase, RNA polymerase makes a complementary copy of a DNA template, building a chain of RNA by attaching the 5’ phosphate of a ribonucleotide to the 3’ hydroxyl of the one preceding it. (1) RNA polymerase does not need a preexisting primer to initiate the synthesis of RNA chain. (2) Firstly, RNA polymerase binds to a specific region of DNA, called promoter, and separate DNA to expose the bases (Fig. 2.6). (3) RNA polymerase recognizes different types of promoters on the basis of which type of σ factor is attached. (4) Even promoters of the same type are not identical to each other, but they do share certain sequence, called consensus sequences by which they can distinguish. (5) A promoter sequence has two important regions: a short AT-rich region about 10 bases upstream of transcription start site, called – 10 sequence or TATA box, and a region about 35 base upstream of start site, called -35 sequence.

  12. III. Transcription

  13. III. Transcription

  14. III. Transcription

  15. III. Transcription (6) RNA polymerase recognizes a particular T or C in the promoter region as a transcription start site and assigned as +1. 5. Initiation and elongation of transcription (1) Core enzyme of RNA polymerase may be randomly bound to DNA. (2) A σ factor binds to the core enzyme of RNA polymerase and then the holoenzyme recognizes and binds to a promoter. (3) When RNA polymerase binds to promoter, a closed complex is formed because the DNA is still double-stranded. (4) The DNA is melt at -10 region and forms a open complex. (5) In the initiation process, a single nucleoside triphosphate (usually A or G) enters and pairs with nucleotide (usually T or C) at +1 in the template strand.

  16. III. Transcription

  17. III. Transcription (6) Then a second nucleoside triphosphate enters and a phosphodiester bond forms between its α phosphate and the 3’ hydroxyl of ribose in the first nucleotide, releasing two phosphates in the form of pyrophosphate and form an initial transcription complex. (7) At this stage, RNA polymerase is not yet free to continue the transcription. A short RNA of about 10 nucleotides is released. This abortive transcription occurs to various degrees on many promoters until the RNA leaves the promoter. (for proofreading) i. Because when the RNA chain grows to a length of about 10 nucleotides, it encounters the σ3.2 loop in active-site channel blocking the exit, called the exit channel. This causes the release of transcript, a phenomenon of abortive transcription.

  18. III. Transcription (8) Eventually, a growing transcript ( at least 12 nucleotides in length) pushes the aside and enters the exit channel, causing the factor to be released from the core RNA polymerase. (9) Once the RNA polymerase has initiated transcription at a promoter, it continues along the DNA , polymerizing ribonucleotides (a process called elongation), until it encounters a transcription termination site on DNA. (Even after transcription is under way, the polymerase often pauses and sometimes even backs up before continuing (for proofreading).

  19. III. Transcription

  20. III. Transcription

  21. III. Transcription Antibiotic rifampin can bind to the wall of active site channel and prevent further elongation of RNA.

  22. 6.Termination of transcription • Bacterial DNA has two basic types of transcription termination sites: Factor (rho, ρ) dependent and factor independent. i. Factor-dependent termination: (i) Factor-dependent terminators have very little sequence in common with each other and so are not readily apparent. Fig. 2.19 illustrates a current model for factor-dependent termination. (ii) Theρfactor attaches to the mRNA at a rut (rho utilization) site if the rut region is not being translated, and form a hexameric ring around it. (iii) The ρ factor moves along the mRNA with the cleavage of ATP until it catches up with paused RNA polymerase at a termination site (ρ-sensitive pause site). (ρ factor has ATPase activity) (iv) The helicase activity of ρ factor dissociates the RNA-DNA hybrid in the transcription bubble, causing the RNA polymerase and the RNA to be released.

  23. A current model for factor-dependent termination

  24. 6.Termination of transcription ii. Factor-independent termination: (i) Factor-independent terminators typically consist an inverted repeat (GC-rich) followed by a short string of A’s, usually 6 residues. (ii) Fig. 2.19 illustrates a current model for factor- independent termination. (iii) The U-rich RNA causes RNA polymerase to pause, allowing a hairpin loop to form, dissociating RNA polymerase and RNA.

  25. A current model for factor-independent termination

  26. III. Transcription 7. rRNA and tRNA synthesis (1) Transcription of the genes for all the RNAs of the cell is basically the same. rRNA and tRNA are synthesis as a precursor, the individual rRNA and tRNA are cut from it. At some point during the processing, the RNAs are modified to make the mature rRNAs and tRNAs. (2) rRNA i. The structural component of ribosome, where the proteins are synthesized. ii. Bacterial ribosome contains three types of rRNA: 16S, 23S and 5S. The 16S and 23S rRNA are made in a precursor and then processed. (They are 18S, 28S and 5.8S in eukaryotic cells). iii. The rRNAs are among the most highly evolutionarily conserved of all the cellular constituents. For this reason, they are always used as the candidate for molecular phylogeny analysis to clarify species.

  27. III. Transcription iv. In addition to their structural role in ribosome, the rRNAs also play a direct role in translation: ex., The 23S rRNA is the peptidetransferase (a kind of ribozyme). The 16S rRNA is directly involved in both initiation and termination of translation. v. in many bacteria, the coding sequences for rRNAs are repeated in 7 to 10 different places around the genome. vi. The rRNAs sometimes are modified, for example methylated. This modification sometimes confers resistance to some antibiotics. (3) tRNA (Fig. 2.21) i. The tRNAs are probably the most highly processed and modified RNAs in cells: Mature tRNA was cut from a much longer molecule and some bases were modified by specific enzymes, creating altered bases such as psedouracil and thiouracil. An enzyme called CCA transferase added the sequence CCA to the 3’ end of mature tRNAs.

  28. The structure of rRNA precursor

  29. The structures of tRNA

  30. IV. Translation @ Translate the sequence of nucleotides in mRNA into the sequence of amino acids in protein, occurring on ribosome. 1. Ribosome consists of one copy each of the 16S, 23S, and 5S rRNAs as well as over 50 different proteins. 2. The complete ribosome, called 70S ribosome, consists of two subunits, the 30S subunit and 50S subunit. The 30S subunit contains 16S rRNA and 21 different proteins. The 50S subunit contains 23S rRNA and 31 different proteins. 3. Reading frame (1) Each three nucleotide-sequence, or codon, in the mRNA encodes a specific amino acid, and the assignment of the codons is known as the genetic code. (2) Translation begins at an initiator codon and ends at a terminator codon, establishing a reading frame of translation.

  31. The structure of ribosome

  32. IV. Translation (3) Before translation can begin, a specific amino acid is attached to nucleotide A of 3’ CCA sequence of each tRNA by its cognate aminoacyl-tRNA synthetase. (4) During translation, the ribosome moves three nucleotides at a time along the mRNA in the 5’- to 3’- direction, allowing aa- tRNAs to pair with larger mRNA through codon-anticodon pairing (Fig. 2.25, 2.26). i. Actually, only two bases is sufficient to direct the codon- anticodon interaction. In other word, codon-anticodon paring is a wobble or degenerated. This pattern of redundancy is due to the pairing between first base in anticodon on the tRNA and last (third) base in the codon is less stringent. As a consequence of wobble, the same codon can have more than one tRNAs. These tRNAs are called cognate tRNA, which carry the same amino acid (Table 2.1).

  33. Aminoacylation of a tRNA by its cognate aminoacyl-tRNA synthetase

  34. Complementary pairing between a tRNAanticodon and an mRNA codon

  35. Wobble pairing between a tRNAanticodon and an mRNA codon

  36. IV. Translation 4. Detail of translation (1) Translation initiation i. Initiation codon(s) – The initiation codon is usually AUG, but in bacteria sometimes are GUG, UUG or AUA. No matter which sequence, it specifies the amino acid methionine (Met). ii. mRNA has sequence called translational initiation region (TIR), which contains an initiation codon and usually a short sequence (~4 bases), called ribosomal binding site (or Shine-Dalgarno sequence), upstream from the initiation codon. In fact, the 5’ end of the mRNA may be some distance from TIR. This region is called the 5’ untranslated region (5’UTR) or leader sequence.

  37. IV. Translation iii. Ribosomal binding site, also called Shine-Dalgarno (SD) sequence is complementary to short sequence located at 3’ of 16S rRNA iv. There are two sites in ribosome: A and P sites for aa-tRNA to enter the ribosome and an E site for tRNA to exist from ribosome. v. Fig. 2.32 diagram the initiation of translation. (i) Initiation factor IF3 binds the 30S subunit to keep it dissociated from 50S subunit during initiation. (ii) IF1 binds to A site to block this site. (iii) The P site of 30S subunit binds the mRNA TIR site. (iv) The formyl-Met (fMet) binds to initiation tRNA, tRNAfMet. (v) The fMet-tRNAfMet enters the P site on 30S subunit in the presence of IF2-GTP.

  38. IV. Translation (vi) IF1 and IF3 are released, the cleavage of GTP on IF2 correctly positions the fMet-tRNAfMet on the P site, and the 50S subunit binds. (vii) The 70S ribosome is ready to accept another aminoacyl- tRNA at A site. (viii) Normally, polypeptides do not have a formyl group attached to their N terminus, which is removed by peptide deformylase after synthesized. In fact, they usually do not even have methionine as their N terminal amino acid, which is removed by methionine aminopeptidase.

  39. The pairing between SD sequence on mRNA and a short sequence close to the 3’ end of 16S rRNA

  40. Initiation of translation

  41. Genetic code

  42. Comparision between met and fMet

  43. IV. Translation (2) Translation elongation (Fig. 2.27) i. When 70S ribosome forms, another aminoacyl-tRNA can enter the A site. (i) Translation elongation factor Tu (EF-Tu) binds another aminoacyl-tRNA and helps position it in A site by using the energy of GTP cleavage. (ii) The Tu-GDP is phosphorylated to Tu-GTP by Ts-GTP, another elongation factor. ii. The peptidyltransferase then joins this coming amino acid to the fMet at P site. iii. The growing peptide is then move to P site by translation elongation factor G (EF-G), making room at A site for another aminoacyl-tRNA and using the energy of GTP cleavage.

  44. The peptidyltransferase reaction

  45. Removal of formyl group and N-formyl-Met

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