MAGNESIUM AND CATALYTIC RNA 273
whether catalytic activity can be recovered (rescued). In 1996, the group pub-
lished a paper inPNAS describing the results when abasic nucleotides were
substituted at 13 critical positions on the hammerhead HH16 construct.^41
Figure 6.13 shows the 13 substituted positions, each marked with a dashed
outline. Figure 6.14 shows the structure of 7 - deazaguanine, a reduced abasic
nucleotide and a phenyl - substituted nucleotide.
For the 13 hammerhead HH16 mutants prepared by the reference 41
researchers, cleavage activity was signifi cantly reduced in all cases. In four
cases, at positions C 3 , A 9 , G 10.1 , and A 13 , addition of the correct base (U, A, G,
or C) rescued the activity of the ribozyme. A9X, for instance, is a ribozyme
where the adenine base at position 9 has been removed to generate an abasic
nucleotide (X = a nucleotide in which H substitutes for the removed base — see
Figure 6.14 ). This altered ribozyme exhibited a 4 × 10 − 4 times lower catalytic
rate than that for the wild - type ribozyme ( kk krel==abasic 22 /.wt 0 0004). When
exogenous adenine (3 mM) was added to the reaction mixture, catalysis was
rescued: k 2 obsA= 012 .min−^1 (or 300 - fold) compared to 1.1 ± 0.2 min − 1 for wild -
type ribozyme. For another variant, the G 10.1 X, where X represents the abasic
nucleotide mutant, the rescue was to wild - type behavior (from 0.04 min − 1 to
1.2 min − 1 ). The ribozyme positions C3X and A13X also exhibited rescue behav-
ior. The reference 41 authors put forth the following hypotheses: (1) Removal
Figure 6.13 Structure of the hammerhead ribozyme HH16. Dashed boxes surround
the 13 substituted positions.
CCA
C
A
C
C
CA A
AC
A
U
UG
UC
U A
AA
ACG C
G C
C GG A
A
CGUCUU
C
C
G
UG
G
6171.5
1.4
1.3
1.2
1.12.5
2.4
2.3
2.2
2.14
53Domain IDomain IIGG
G
G
GG
GG
G11.4
11.3
11.212
13
1411.1 G
15.115.3
15.415.210.4
10.3
10.2
10.1
9
8
716.216.416.3scissile bond16.15'3'stem (helix) Istem (helix) II
L2.4L2.3 L2.2L2.1stem (helix) III3' 5'