Section O: RNA Processing and RNPs.Yang Xu, College of Life Sciences Section P Genetic code and tRNA P1 The genetic code P2 tRNA structure and function.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Section P Genetic code and tRNA

P1 The genetic code

P2 tRNA structure and function

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

P1 The genetic codeP1 The genetic code

• Nature• Deciphering• Feature• Effect of Mutation• Universality• ORFs• Overlapping Genes

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

NatureNature• Genetic code is a triplet code (to be grouped in 3nt);• The triplet codons are adjacent (non-overlapping);• They are not separated by punctuation (comma-less). • Because many of the 64 codons specify the same

amino acid, the genetic code is degenerate; • So that the genetic codons have redundancy. As more gene and protein sequence information has been

obtained, it has become clear that the genetic code is very nearly, but not quite, universal. This supports the hypothesis that all life has evolved from a single common origin.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

DecipheringDeciphering

• In the 1960s, Marshall Nirenberg developed a “cell-free protein synthesizing system” from E. coli (细胞外蛋白合成体系 ).

• To determine which amino acids were being polymerized into polypeptides, it was necessary nucleotide phosphorylase was used to make synthetic mRNAs that were composed of only one nucleotide, that is poly (U), poly (C), poly (A) and poly (G).

• If protein synthesis took place after adding one of these mRNAs, then in one of the 20 reaction tubes, the radioactivity could show the formation of polypeptide.

• In this way, it was found that: – Poly (U) caused the synthesis of poly-phonylalanine, – Poly (C) coded for poly-proline– Poly (A) for poly-lysine– Poly (G) did not work because it formed a complex secondary structure.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

DecipheringDeciphering

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

DecipheringDeciphering• The precise sequence of the triplet

codon can only be worked out if additional information is available.

• Towards the end of the 1960s, it was found that synthetic tri-nucleotides could attach to the ribosome

and bind their corresponding

aminoacyl-tRNAs.

• Upon filtering through a membrane, only the complex of ribosome, synthetic triplet and aminoacyl-tRNA was retained on the membrance.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

FeatureFeature

• The genetic code is degenerate (or it shows redundancy). This is because 18 out of 20 amino acids have more than one codon to specify them, called synonymous codons .

• Only methionine and tryptophan have single codons.

• The synonymous codons are not positioned randomly, but are grouped in the table. Generally they differ only in their third position.

• In all cases, if the third position is a pyrimidine, then the codons specify the same amino acid (are synonymous).

• In most cases, if the third position is a purine the codons are also synonymous.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

UniversalityUniversality

• For a long time after the genetic code was deciphered, it was thought to be universal, that is the same in all organisms.

• However, since 1980, it has been discovered that mitochondria, which have their own small genomes, use a genetic code that differs slightly from the standard, or ‘universal’ code. Indeed, it is now known that some other unicellular organisms also have a variant genetic code.

P254, P1.2

Modifications of the genetic codeCodon Usual Alternative Organelle/organism

AGA Some AnimalAGG Mitochondria

AUA Ile Met Mitochondria

CGG Arg Trp Plant Mitochondria

CUN Leu Thr Yeast Mitochondria

AUU IleGUG Val Start Some ProkaryotesUUG Leu

UAAUAG

UGA Stop Trp Mit. Mycoplasma

Arg Stop, Ser

Stop Glu Some Protozoans

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Overlapping GenesOverlapping Genes• Generally overlapping genes occur where the genome size is

small and there is a need for greater information storage density.

• In viruses, for example, the phage ΦΧ174 makes 11 proteins of combined molecular mass 262 kDa from a 5386 bp genome. Without overlapping genes, this genome could encode at most 200 kDa of protein. Three proteins are encoded within the coding regions for longer proteins.

• In prokaryotes, the ribosomes simply have to find the second start codon to be able to translate the overlapping gene and they may achieve this without detaching from the template.

• Eukaryotes have a different way of initiating protein synthesis and tend to make use of alternative RNA processing to generate variant proteins from one gene.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

P2 tRNA Structure P2 tRNA Structure and Functionand Function

• tRNA Primary Structure• tRNA Secondary Structure• tRNA Tertiary Structure• tRNA Function• Aminoacylation of tRNA• Aminoacyl-tRNA Synthetases• Proofreading Robert Holley(46y)

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

tRNA Primary StructuretRNA Primary Structure• tRNAs are the adaptor molecules that deliver ammo acids to the

ribosome and decode the information in mRNA. Their primary structure (i.e. the linear sequence of nucleotides) is 60-95 nt long, but most commonly 76 nt.

• They have many modified bases sometimes accounting for 20% of the total bases in any one tRNA molecule. Indeed, over 50 different types of modified base have been observed in the several hundred tRNA molecules characterized to date, and all of them are created post-transcriptionally.

• Seven of the most common types are shown in Fig. 1 as nucleosides.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

tRNA Secondary StructuretRNA Secondary Structure• All tRNAs have a common secondary structure (i.e. base

pairing of different regions to form stems and loops), the cloverleaf structure.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

---aa accept arm

loading aa at 3’ end

---DHU loop:

contact with AARS

---anti-codon loop:

34th is wobble base

---TΨC loop:

contact with 5s rRNA

34---extra loop: (Variable arm) classification marker ?

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

tRNA Tertiary StructuretRNA Tertiary Structure

• There are hydrogen bonds (tertiary hydrogen bonds) that help form the 3-D structure of tRNA molecules.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

tRNA FunctiontRNA Function

• tRNAs are joined to amino adds to become aminoacyl-tRNAs

(charged tRNAs) in a reaction called aminoacylation.

• It is these charged tRNAs that are the adaptor molecules in

protein synthesis.

• Special enzymes called aminoacyl-tRNA synthetases carry out

the joining reaction which is extremely specific (i.e. a specific

amino acid is joined to a specific tRNA).

• These pairs of specific amino acids and tRNAs, or tRNAs and

aminoacyl-tRNA synthetases are called cognate pairs, and the

nomenclature used is shown in Table 1 (page 258).

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Aminoacylation of tRNAAminoacylation of tRNA• The general aminoacylation reaction is shown in Fig. It is a

two-step reaction driven by ATP:

• In the first step, AMP is linked to the carboxyl group of the amino acid giving a high-energy intermediate called an aminoacyl adenylate.

• The hydrolysis of the pyro-phosphate released (to two molecules of inorganic phosphate) drives the reaction forward.

• In the second step, the aminoacyl adenylate reacts with the appropriate uncharged tRNA to give the aminoacyl-tRNA and AMP.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Aminoacyl-tRNAAminoacyl-tRNAStep 1

Setp 2

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Aminoacyl-tRNA SynthetasesAminoacyl-tRNA Synthetases• Despite the fact that they all carry out the same reaction of

joining an amino acid to a tRNA, the various synthetase enzymes can be quite different.

• They fall into one of four classes of subunit structure, being either

• The polypeptide chains range from 334 to over 1000 amino acids in length, and these enzymes contact the tRNA on the underside (in the angle) of the L-shape.

• They have a separate amino acid-binding site. The synthetases have to be able to distinguish between about 40 similarly shaped, but different, tRNA molecules in cells, and they use particular parts of the tRNA molecules, called identity elements, to be able to do this (Fig. 4).

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Identity Elements (Paracodon)

AARS

tRNA binding site aa binding site

Paracodon of tRNA loading Amino Acid（ R）

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Identity Elements in various tRNA Molecules

tRNAAla

tRNAfMet

tRNAPhe

tRNASer

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

Position of Identity Elements

Anti-codon loop

C,D,E,F,G,H,I,K,M,N,PQ,R,T,V,W,Y

Extra loopA, F, L, R

TΨC loop aa arm: A,D,G,H,N,S,T,V,W

73th siteA.C.D.E.F.G.H.I.K.L.M.N.P.Q.R.S.V.W.Y.

Section O: RNA Processing and RNPs. Yang Xu, College of Life Sciences

That’s all for Section PThat’s all for Section P