Chemie, struktura a interakce nukleových kyselin
2008 4.-5.EP/6-7.PŘEDNÁŠKA
Lokální struktury DNA a metody jejich analýzy
Parametry různých typů ds DNA
Metody analýzy lokálních struktur DNA
Ohyby v DNA
Typy lokálních struktur stabilizovaných
nadšroubovicovým vinutím
Strukturní rozhraní
Výskyt lokálních struktur DNA in vivo
Polymorphy of the DNA double helix
B. sublilis and B. brevis DNAs have the same
G+C content and different nucleotide sequence
B. subtilis
B. brevis
DNA structures from X-ray crystal analysis
DNA double helix is polymorphic
depending on the nucleotide sequence
MICROHETEROGENEITY OF THE DNA DOUBLE HELIX FORMS
Studies of the detailed relationships between nucleotide sequence and DNA structure
became feasible by the end of the 70s, when organic synthesis had been developed to the
point where oligodeoxynucleotides (ODN) could be produced in the purity and quantity
necessary for the preparation of single crystals for X-ray diffraction (and NMR) studies.
Three main families of DNA forms were identified by crystallographic analysis of ODN:
right-handed A and B-forms and the left-handed Z-form.
B-, A- and Z-helices
The A-, B- and Z-helices have distinctly different shapes which are due to the specific
positioning and orientation of the bases with respect to the helix axis. In A-DNA, the base
pairs are displaced from the helix axis, the major groove is very deep, and the minor
groove is very shallow. In B-DNA the major and minor grooves are of similar depths and the
helix axis is close to the base pair center. In Z-DNA the minor groove is deep and the
major groove is convex. In A- and B-DNA a single nucleotide can be considered as the
repeat unit, while in Z-DNA the repeat unit is a dinucleotide.
In A-duplexes base pairs are heavily tilted in contrast
to base pairs in B-duplexes which are almost
perpendicular to the helical axis. (Table 1). Many of
the structural differences between the helices arise
from the puckering of the sugar ring; C3'-endo is
typical for A-DNA, while in Z-DNA C3'-endo
alternates with C2'-endo. In B-DNA sugar pucker
tends to favor the C2'-endo or C1'-exo,but the
distribution of conformations is much broader than in
A- and Z-DNA.
A B Z
The right-handed A- and B-forms have the anti glycosidic bond, whereas in the
left-handed Z-helix the orientation alternates between syn (for purines) and
anti (for pyrimidines). In the latter structure the orientation around the C4'C5'
bond with respect to the C3' atom alternates between gauche+ and trans
conformations for cytidine and guanosine, respectively. The alternating
features of Z-DNA result in the zig-zag shape of its sugar-phosphate
backbone, from which the name was derived. The changes in the backbone and
glycosidic-bond conformations are accompanied by substantial variations in the
stacking interactions between successive base pairs in Z-DNA. Methylation or
bromination of cytosines at position 5 (studied mainly in ODNs with alternating
C-G sequence) stabilizes Z-DNA. Under certain conditions even non-alternating
sequences of purines and pyrimidines can assume the conformation of Z-DNA
with thymines in a syn orientation. The outer surface features of such a Zhelix
are different at the non-alternating sites but the backbone is similar to
that observed with alternating sequences.
Local DNA Structures and Nucleotide Sequence
The significant variations in some of the global parameters (Table 2), dependent on
nucleotide sequence, result in local changes along the DNA double helix. Such
relations have been analyzed in detail by several authors and reviewed by Shakked
and Rabinovich. In A- and B-DNA these variations seem to be determined mainly by
the specific interactions between the stacked base pairs and also to some extent by
neighboring bases. In particular, homopolymer dinucleotide steps show a wide
spectrum of stacking characteristics which are markedly neighbor dependent. On the
other hand pyrimidine-purine steps in A-DNA (especially the C-G steps) often display
a low twist and high slide that are only slightly dependent on neighboring steps. In ZDNA
the shape of the helix surface changes significantly due to deviations in the
regular alternation of the purine-pyrimidine sequence while the sugar-phosphate
backbone does not change. The effect of the nucleotide sequence on the fine
geometrical features of each DNA form has been clearly demonstrated but not fully
elucidated. The emerging rules should, however, be considered as tentative since
they were based on a relatively small number of examples. The well-known
"Calladine's rules" are now perceived to be incomplete and to neglect important
factors other than the steric clash of purine rings.
DNA Hydration
Information about the organization of water molecules in DNA forms has been gained
from X-ray diffraction analysis of crystals. Distinct hydration patterns were observed in
the major and minor grooves and around the sugar-phosphate backbone. It was proposed
that in DNA with a mixed nucleotide sequence hydration of the backbone is related to
global conformation. In A- and Z-DNA a chain of water molecules can bridge the
phosphate oxygens along the backbone. There are more water molecules around each
phosphate group in the B-DNA but almost no water bridges between the phosphate
oxygens, as the distances between phosphate oxygens in this DNA form are too great to
be linked with a single water molecule. It appears that specific nucleotide sequences that
create local changes in the DNA double helix may also affect the backbone hydration
pattern. Even greater dependence of the hydration patterns on nucleotide sequence has
been found in the DNA grooves. In A-DNA specific hydration patterns occur in the major
grooves. A string of well ordered water molecules hydrogen bonded to oxygen and
nitrogen atoms in the minor groove has been found in the central AATT sequence of the
B-DNA dodecamer d(CGCGAATTCGCG). This specific hydration of B-DNA, called "spine
of hydration", significantly contributes to DNA stability. Studies of further B-DNA
helices revealed two ribbons of water molecules along the walls of wide regions of the
minor groove while narrow regions of the minor groove contained an ordered zig-zag spine
of hydration. It appears that the interdependence between nucleic acid structure and the
solvent represents one of the bases for DNA double helix polymorphy.
Metody analýzy lokálních stuktur DNA
DNA footprinting
mapping of DNA interactions
Enzymatic probe (DNAase I)
Chemical probe - DEPC
Single-strand selective chemical probes of the DNA structure
Discovery of the cruciform
in sc DNA
D M J LILLEY, 1981
12.11. - 6. předn.
a. DR. L. HAVRAN: SYNTHESA OLIGONUKLEOTIDŮ (ca. 10 min)
b. Prof. M. VORLIČKOVÁ: CD DNA (a 40 min)
23
LEFT-HANDED Z-DNA
alternating pu-py
CRUCIFORM
inverted repeat
CURVATURE
4-6 A's in phase with
the helix turns
SINGLE-STRANDED region
AT-rich
Text
TRIPLEX structure
homopu.
homopy
HAIRPIN
SUPERCOIL
Negative SUPERCOILING stabilizes
local DNA structures
Physical methods such as NMR and X-ray analysis indispensable in the research of
linear DNA structures are of limited use in studies of local structures stabilized
by supercoiling
INVERTED REPEAT
DNA B-Z junction
Strukturní rozhraní mezi B- a Z-DNA
detekce pomocí chemické strukturni sondy
konec/12.11.08
17.18. J. Šponer - mat. modelování NA (ca
45 min)
DNA triplexes
their identification by chemical probes
INTERmolecular
INTRAmolecular
pu
py
1990 existence of triplex H-DNA in cells
was demostrated in Paleček's laboratory
Homopy.homopy sekvence se
zrcadlovou symetrii je potřebná
pro vznik triplexu H-DNA
*H-DNA může vzniknout i v jiných sekvencích
E. Trifonov, Weizmann Inst, Rehovot
M. Frank-Kamenetskii, Boston Univ
S. Mirkin, Univ. Illinois, Chicago
D. Lyamichev ...........
všichni původně v Moskvě
G-quartet
DOPLNĚK k předn. prof. M.Vorlíčkové
Výskyt lokálních struktur DNA
v prokaryotních a eukaryotních buňkách
Proc. Natl. Acad. Sci. USA
87 (1990) 8373-8377
Chemická modifikace DNA v buňkách
pomocí komplexu OsO4 (Os,bipy) a
její využití pro testování - DNA
Strukturní přechod DNA duplex křížová
forma v buňce může
informovat o superhelikální hustotě
DNA a o jejich změnách
působených změnami prostředí nebo
genetickými faktory
Salt shock
Cruciform structures in E. coli cells
TRIPLEX DNA V BUŇKÁCH PROKÁZANÝ POMOCÍ Os,bipy
P. Karlovský, P. Pecinka, M. Vojtísková, E. Makaturová, E. Palecek,
FEBS Letters 274 (1990)39-42
Konformer H-y5
pravděpodobně
v buňkách převažuje
Disociace nukleosomu vede k aktivaci transkripce a tvorbě negativní
nadšroubovice (supercoil) schopné indukovat lokální struktury.
Transkripce může být aktivována vazbou specif. proteinu
(např. Z-binding ) posunující rovnováhu ve prospěch
lokální struktury, následované vznikem pozitivní nadšroubovice
a ztrátou nukleosomu
Merry Christmas and
a Happy New Year
2009!