overcoming conformational paradox: template circularization might prevent the formation of double...
TRANSCRIPT
OVERCOMING CONFORMATIONAL PARADOX:Template circularization
might prevent the formation of double strands during RNA replication
Alexander Chetverin
Institute of Protein Research of the Russian Academy of SciencesPushchino, Moscow Region; [email protected]
Life: a form of propagation of a genetic material
At present, the simplest imaginable way for accomplishing this goal is provided by the concept of the RNA world, because RNA is the only type of
molecules that can serve both as templates and catalysts for their amplification.
Arguments for the feasibility of the RNA world
1. Nucleotides can spontaneously form under conditions that existed on the early Earth or a similar planet.
2. Activated nucleotides can spontaneously polymerize into long (≥ 40 nucleotides) strand.
3. RNA molecules can spontaneously recombine to produce even longer strands.
4. Pools of random oligonucleotides consisting of 1012 – 1015 molecules (0.01 – 10 μg of a 40 nt-long RNA) always contain molecules from which one can select ribozymes (RNA enzymes) with virtually any desired catalytic function.
5. Selected ribozymes can catalyze the synthesis of RNA strands that are complementary to RNA templates.
A problem not yet solved:
The synthesized complementary strand and the template form a double helix along the entire length.Thus, the template and the synthesized complementary copy are locked in the double helix and therefore unavailable as templates for the synthesis of more RNA copies.
Hence, no propagation of the genetic material(NO LIFE) is possible.
“Something inconsistent with common experience or having contradictory qualities”
Webster’s Dictionary
Paradox:
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CH3
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1'T A
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Complementary (matching) nucleotides
For a complementary strand be synthesized according to the Watson-Crick rules it must base pair with a template, i.e., be a part of the double helix.
However, to enable further replication, the template and the complementary copy must remain single stranded, i.e., unpaired.
Double helix is neededfor a template-directed RNA synthesis,
but it prevents RNA amplification
Like the artificial ribozymes, hypothetical replicases of the ancient RNA world must had encountered
with this problem
Conformational paradox:
Gilbert W. & de Souza S.J. (1999) Introns and the RNA world. In The RNA World,2nd edn., pp. 221–231, CSHL Press, Cold Spring Harbor, NY.
Double-stranded DNA
In Polymerase Chain reaction (PCR),the paradox is overcome by temperature cycling
Duplex melting (>90°C)Primer annealing (50-60°C)Strand elongation (72°C)
Temperature cycling is not a proper solution of the conformational paradox in the RNA world, as it generates another (chemical)
paradox:
divalent cations (Mg2+, Ca2+) are needed for the catalysis of RNA synthesis at low temperatures,
but they catalyze RNA hydrolysis (depolymerization) at the high temperatures required for melting RNA duplexes
Spiegelman S. et al. (1968) The mechanism of RNA replication. Cold Spring Harbor Symp. Quant. Biol. 33, 101-124.
Double-stranded RNA
Partially double-stranded RNA
Infectious (+) strand
Small (RQ) RNAs
Replication of the Qβ phage RNA:a double-stranded intermediate?
Step 1
Step 2
or% о
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НК
Время, мин
There are no double-stranded intermediatesin the Qβ RNA replication cycle
Weissmann С. et al. (1968) In vitro synthesis of phage RNA: The nature of the intermediates. Cold Spring Harbor Symp. Quant. Biol. 33, 83-100.
Single strand-specific ribonuclease
• All double-stranded and partially double stranded structures are isolation artifacts: they are induced by any agent that denature the replicase: phenol, detergents, or protease.• Like ribozymes, Qβ replicase cannot use the double
helix as a template.
Double-stranded RNA
Single-stranded RNA
How does Qβ replicase overcomethe conformational paradox?
Possible solution No. 1:The double helix is unwound by Qβ replicase itself acting like a zipper to separate the template and the complementary nascent strand, which are then stabilized in the single stranded conformation by the intramolecular secondary structure.
Weissmann C. et al. (1968) In vitro synthesis of phage RNA: the nature of the intermediates. Cold Spring Harbor Symp. Quant. Biol. 33, 83–100.
• The double helix formed by complementary RNA strands are thermodynamically more stable than are the intrastand secondary structures: If a mixture of complementary is annealed (melted and then slow cooled), they are completely converted into double helix.
• Within the replicative complex, the template and the nascent strands are close to one another, which favors their annealing.
• These stands immediately collapse into the double helix under action of proteases and detergents that cannot affect the stability of the RNA secondary structure, but destroy or unfold the protein structure.
However:
Possible solution No. 2:The unzipped strands are kept from annealing by a single strand-binding protein that coats the strands along the entire length.
Weissmann C. et al. (1968) In vitro synthesis of phage RNA: the nature of the intermediates. Cold Spring Harbor Symp. Quant. Biol. 33, 83–100.
The replicative complex remains single-stranded even in a purified cell-free system that contains no proteins but Qβ replicase.
However:
Possible solution No. 3:The replicase holds the 3‘ end of the template and the 5‘ end of the nascent strand during the entire replication cycle. This poses topological constraints to winding the strands into the double helix.
Weissmann C. et al. (1968) In vitro synthesis of phage RNA: the nature of the intermediates. Cold Spring Harbor Symp. Quant. Biol. 33, 83–100.
Several nascent strands can simultaneously be synthesized on the same template strand.
However:
Thach S.S. & Thach R.E. (1973) Mechanism of viral replication. I. Structure of replication complexes of R17 bacteriophage. J. Mol. Biol. 81, 367–380.
Матрица
Растущая цепь
3'
5'
5'
Растущая цепь
Матрица
3'
5'
5'
Functional circularity:The ability of a template to present to replicase its 5 end, ′
in addition to the 3 end, at the initiation step′
Haruna I. & Spiegelman S. (1965) Recognition of size and sequence by an RNA replicase. Proc. Natl. Acad. Sci. USA 54, 884–886.
3'5'
The Amphora model: The template strand could form a circle if it had complementary termini capable of base-pairing; the replicase could then recognize the terminal helix (“panhandle”).
Template activity of the genomic RNA of phage Qβ drastically drops upon its fragmentation into two halves.It looked like Qβ replicase may sense during initiation if the template strand is intact.
Weissmann C., Billeter M.A., Goodman H.M., Hindley J. & Weber H. (1973) Structure and function of phage RNA. Annu. Rev. Biochem. 42, 303–328.
Replicable RNAs indeed have complementary termini
• The complementary stretches are too short (3-4 nt) to form a stable circular structure.
• Inability of the fragmented template to replicate might be a mere consequence of the fact that the initiator 3’ end of the complementary strand cannot be synthesized.
However:
PPPGGG CCCAOH5' 3'
PPPGGG CCCAOH5' 3'
HOACCC GGGPPP3' 5'X
Munishkin A.V., Voronin L.A., Ugarov V.I., Bondareva L.A., Chetverina H.V. & Chetverin A.B. (1991) Efficient templates for Qβ replicase are formed by recombination from heterologous sequences. J. Mol. Biol. 221, 463-472.
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All known replicale RNAs are capable of formation a hairpin that involves the 3‘ и 5‘ terminal structures
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Mung bean
RNaseRNaseV1
RQ135 RNA
Ugarov V.I. & Chetverin A.B. (2008) Functional circularity of legitimate Qβ replicase templates. J. Mol. Biol. 379, 414-427.
Is there any functional linkagebetween the 3’ и 5’ ends of replicable RNAs?
3’ fragment
5 fragment
RQ135 RNA
Point mutations G → A
Ugarov V.I. & Chetverin A.B. (2008) Functional circularity of legitimate Qβ replicase templates. J. Mol. Biol. 379, 414-427.
Damage to the 5’ terminus results in a dropof the initial rate of RNA synthesis
Reaction time, s
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Ugarov V.I. & Chetverin A.B. (2008) Functional circularity of legitimate Qβ replicase templates. J. Mol. Biol. 379, 414-427.
Point mutations at the 5’ end increasethe requirement of RNA replication
for the concentration of the initiator nucleotide (GTP)
GTP concentration, μM
A
A
AA
Ugarov V.I. & Chetverin, A. B. (2008). Functional circularity of legitimate Qβ replicase templates. J. Mol. Biol. 379, 414-427.
Initiation time (before the addition of ATA), min
Mutations at the 5’ end of decreasethe rate and yield of initiation
Varied time ofinitiation (GTP only)
Initiation stop (+aurintricarboxylic
acid: ATA)Elongation
ATP+CTP UTP
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Ugarov V.I. & Chetverin, A. B. (2008). Functional circularity of legitimate Qβ replicase templates. J. Mol. Biol. 379, 414-427.
Mutations at the 5’ end of the template destabilize the post-initiation replicative complex
Time of incubation with ATA, min
+ATA Elongation ATP+CTP UTP
10-min initiation (+GTP)
Varied time ofincubation with ATA
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Thus, the 5’ end of the template interacts with the 3’ end at the initiation step and thereafter.
Nascent strand
Replicase
Terminal helix Template
Nascent strand
Nascent strand
The terminal helix of the template might, by itself or with the assistance of a replicase molecule, fasten the template in a circular conformation and thereby help to keep the replicative complex single stranded during the elongation phase.
Similarly, the conformation paradox might be overcome at RNA replication in the ancient RNA world.
There is growing body of evidence that various viral RNAs and even eukaryotic
mRNAs form circles.
This feature might be a relic inherited by the contemporary DNA world from the RNA world
in which a circular structure was a prerequisite for the ability of genetic material to
propagate.