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Previous Article | Next Article 
Molecular and Cellular Biology, December 2001, p. 7995-8006, Vol. 21, No. 23
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.23.7995-8006.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Highly Frequent Frameshift DNA Synthesis by
Human DNA Polymerase µ
Yanbin
Zhang,
Xiaohua
Wu,
Fenghua
Yuan,
Zhongwen
Xie, and
Zhigang
Wang*
Graduate Center for Toxicology, University of
Kentucky, Lexington, Kentucky 40536
Received 11 April 2001/Returned for modification 24 May
2001/Accepted 28 August 2001
 |
ABSTRACT |
DNA polymerase µ (Polµ) is a newly identified member of the
polymerase X family. The biological function of Polµ is not known, although it has been speculated that human Polµ may be a somatic hypermutation polymerase. To help understand the in vivo function of
human Polµ, we have performed in vitro biochemical analyses of the
purified polymerase. Unlike any other DNA polymerases studied thus far,
human Polµ catalyzed frameshift DNA synthesis with an unprecedentedly
high frequency. In the sequence contexts examined, 
1 deletion
occurred as the predominant DNA synthesis mechanism opposite the
single-nucleotide repeat sequences AA, GG, TT, and CC in the template.
Thus, the fidelity of DNA synthesis by human Polµ was largely
dictated by the sequence context. Human Polµ was able to efficiently
extend mismatched bases mainly by a frameshift synthesis mechanism.
With the primer ends, containing up to four mismatches, examined, human
Polµ effectively realigned the primer to achieve annealing with a
microhomology region in the template several nucleotides downstream. As
a result, human Polµ promoted microhomology search and microhomology
pairing between the primer and the template strands of DNA. These
results show that human Polµ is much more prone to cause frameshift
mutations than base substitutions. The biochemical properties of human
Polµ suggest a function in nonhomologous end joining and V(D)J
recombination through its microhomology searching and pairing
activities but do not support a function in somatic hypermutation.
| |
INTRODUCTION |
Many cellular processes require a
DNA polymerase (Pol), including DNA replication, DNA repair,
recombination, translesion DNA synthesis, and somatic hypermutation.
Pol
, Pol
, Pol
, and Pol
are replicative DNA polymerases in
eukaryotes (16, 29). Pol
is a major polymerase required
for DNA damage-induced mutagenesis (21, 22). Pol
is
likely involved in repair of DNA interstrand cross-links
(27). Pol
, Pol
, and Pol
belong to the Y (UmuC) family of DNA polymerases and are involved in error-free and
error-prone translesion synthesis opposite various DNA lesions
(9, 20, 24, 31).
Pol
is a major repair synthesis polymerase during base excision
repair in higher eukaryotes (17, 33, 36). Pol and terminal deoxynucleotidyltransferase (TdT) are members of the DNA
polymerase X family (13). TdT catalyzes nucleotide
addition to DNA in a template-independent manner (3, 5).
This enzyme is restricted to lymphoid tissues and functions during
V(D)J recombination of the immunoglobulin genes and T-cell receptor
genes (3, 5, 32). Most recently, the two newest members of
the DNA polymerase X family, designated Pol
and Polµ, have been
identified in humans (1, 8, 10). According to protein
sequence comparisons, Pol is more closely related to Pol while
Polµ is phylogenetically closer to TdT (1, 8). The
biological functions of Pol and Polµ remain to be defined. It has
been speculated that Pol may play a role in meiosis
(10) and that Polµ may be a somatic hypermutation polymerase (8).
V(D)J recombination and somatic hypermutation are two essential
mechanisms for generating antibody diversity during immunoglobulin development. V(D)J recombination requires DNA strand cleavage by the
lymphoid-specific RAG1 and RAG2 proteins, and the resulting double-strand breaks are repaired by a nonhomologous end joining (NHEJ)
mechanism similar to that employed by other tissues to repair the
broken ends of DNA. Proteins involved in NHEJ include Ku70, Ku80,
DNA-PKcs, XRCC4, and DNA ligase IV
(25). More proteins are likely needed during NHEJ, such as
a specific factor that promotes microhomology search and microhomology
pairing. Somatic hypermutation introduces mainly point mutations into
the V region of immunoglobulin genes at a rate of
10
3 to 104/base
pair/generation, which is 
106-fold higher than
the spontaneous mutation rate in the rest of the genome
(30). Thus, somatic hypermutation probably requires a
low-fidelity DNA polymerase that possesses extraordinarily high error
rates of misincorporations opposite undamaged template bases (4). However, this hypothetical hypermutation polymerase
has eluded extensive studies thus far.
To help understand the biological function of human Polµ, we have
extensively analyzed its biochemical properties. Surprisingly, we found
that human Polµ catalyzes frameshift DNA synthesis with an
unprecedentedly high frequency. Furthermore, when the primer 3' end
contains base mismatches, human Polµ efficiently realigns the primer
strand to form new base pairings further downstream with the template
bases. These remarkable biochemical properties do not support a role
for human Polµ in somatic hypermutation and suggest that human Polµ
may function in NHEJ and V(D)J recombination by promoting microhomology
search and microhomology pairing.
| |
MATERIALS AND METHODS |
Materials.
A mouse monoclonal antibody against the
His6 tag was purchased from Qiagen (Valencia,
Calif.). Alkaline phosphatase-conjugated anti-mouse immunoglobulin G
was from Sigma Chemical Co. (St. Louis, Mo.). Oligonucleotides were
synthesized by Operon (Alameda, Calif.). The yeast rad30
deletion mutant strain BY4741rad30
(MAT his3 leu2 met15
ura3 rad30) was purchased from Research Genetics (Huntsville, Ala.). The Klenow fragment of Escherichia coli DNA
polymerase I was purchased from Gibco BRL (Bethesda, Md.),
Pfu DNA polymerase was obtained from Stratagene (La Jolla,
Calif.), and restriction endonucleases were from New England Biolabs
(Beverly, Mass.). Human Pol was purified to apparent homogeneity as
previously described (38).
Gene constructions.
Human Polµ is encoded by the
POLM gene (1, 8). The POLM cDNA was
obtained by PCR amplification from human pancreas cDNAs using
Pfu DNA polymerase and two primers,
5'-GCTCTAGAGTCGACATGCTCCCCAAACGGCGG (PolMF primer) and
5'-ACATGCATGCAGGCCCCACCACAGC. The resulting 1.8-kb PCR
product was then cloned into the SalI and SphI
sites of the vector pEGUh6, yielding pEGUh6-POLM. The POLM
gene was verified by DNA sequencing. This expression construct contains the 2µm origin for multicopy plasmid replication, the URA3
gene for plasmid selection, the inducible GAL1/GAL10
promoter, and six histidine codons preceding the ATG initiator codon of
the human POLM gene. To construct the mutant polm
gene, the pEGUh6-POLM plasmid was amplified by PCR with the PolMF
primer and the primer 5'-CCCAAGCTTAGGATGGGCAGGGCCTCG. The
resulting 1.2-kb DNA fragment was then cloned into the SalI
and HindIII sites of the vector pEGUh6, yielding
pEGUh6-polmC83. The mutant gene was verified by DNA sequencing.
Expression of pEGUh6-polmC83 in yeast cells produces the mutant
protein PolµC83 missing the C-terminal 83 amino acids of human
Polµ.
Purification of human Polµ.
Yeast BY4741rad30 cells
harboring pEGUh6-POLM were grown in minimum medium containing 2%
sucrose for 2 days. Expression of Polµ was induced by diluting the
culture 10-fold in 16 liters of YPG (2% Bacto Peptone, 1% yeast
extract, 2% galactose) medium supplemented with 0.5% sucrose and
incubation for 15 h at 30°C with shaking. The collected cells
(100 g) were homogenized with zirconium beads in a Bead-Beater
(Biospec Products, Bartlesville, Okla.) in an extraction buffer
containing 50 mM Tris-HCl, pH 7.5, 600 mM KCl, 5 mM
-mercaptoethanol, 10% sucrose, and protease inhibitors
(37). The clarified extract (120 ml) was loaded onto
two connected HiTrap chelating columns (5 ml each) charged with
NiSO4 (Amersham Pharmacia Biotech, Piscataway,
N.J.), followed by washing the column sequentially with 100 ml of Ni
buffer A (20 mM KH2PO4, pH
7.4, 0.5 M NaCl, 10% glycerol, 5 mM -mercaptoethanol, and protease
inhibitors) containing 10 mM imidazole and 100 ml of Ni buffer A
containing 35 mM imidazole. Bound proteins were eluted with a linear
gradient of 35 to 108 mM imidazole. The
His6-tagged human Polµ was identified by
Western blot analyses using a mouse monoclonal antibody specific to the
His6 tag. The pooled sample (150 ml) was
concentrated by polyethylene glycol 10,000 and desalted through 5 connected Sephadex G-25 columns (5 ml each) (Amersham Pharmacia
Biotech) in fast-protein liquid chromatography (FPLC) buffer A (50 mM
Tris-HCl, pH 7.5, 1 mM EDTA, 10% glycerol, and 5 mM
-mercaptoethanol) containing 80 mM KCl. The resulting sample (50
ml) was loaded onto an FPLC Mono S HR5/5 column (Amersham Pharmacia Biotech) and eluted with a 30-ml linear gradient of 80 to 600 mM KCl in FPLC buffer A. Human Polµ was eluted at 250 mM KCl. The
Mono S fractions of human Polµ were concentrated to 250 µl by
polyethylene glycol 10,000 and loaded onto an FPLC Superdex 200 gel
filtration column that had been equilibrated in FPLC buffer A
containing 150 mM KCl. Human Polµ was eluted at the 60-kDa position.
DNA polymerase assays.
A standard DNA polymerase reaction
mixture (10 µl) contained 25 mM
KH2PO4 (pH 7.0), 5 mM
MgCl2, 5 mM dithiothreitol, 100 µg of bovine
serum albumin/ml, 10% glycerol, 50 µM deoxynucleoside triphosphates
(dNTPs) (dATP, dCTP, dTTP, and dGTP individually or together as
indicated), 50 fmol of a DNA substrate containing a
32P-labeled primer, and purified DNA polymerase
as indicated. After incubation at 30°C for 10 min or as otherwise
indicated, reactions were terminated with 7 µl of a stop solution (20 mM EDTA, 95% formamide, 0.05% bromophenol blue, and 0.05% xylene
cyanol). The reaction products were separated by electrophoresis on a
20% denaturing polyacrylamide gel and visualized by autoradiography.
Kinetic analysis of human Polµ.
Kinetic analysis of human
Polµ was performed as previously described (6, 38).
Briefly, the assays were performed using 50 fmol of a DNA substrate
containing a 5' 32P-labeled primer, 0.75 ng (14 fmol) of purified Polµ, and increasing concentrations of each dNTP
(dATP, dCTP, dTTP, or dGTP). Incubations were for 10 min at 30°C
under standard DNA polymerase assay conditions. Longer incubations of
up to 120 min were required to detect some misincorporations by human
Polµ. The reaction products were separated by electrophoresis on a
20% denaturing polyacrylamide gel and quantitated by scanning
densitometry. The observed enzyme velocity (v) was plotted
as a function of dNTP concentration. The plotted data was fitted by a
nonlinear regression curve to the Michaelis-Menton equation,
v = (Vmax × [dNTP])/(Km + [dNTP]), using the
SigmaPlot software. Vmax and
Km values for the incorporation of the
correct and the incorrect nucleotides were obtained from the fitted
curves. The relative error rate (finc)
of nucleotide incorporation was calculated from the equation:
finc = (Vmax/Km)incorrect/(Vmax/Km)correct.
| |
RESULTS |
Purification of human Polµ.
Following its expression in
yeast cells, we have purified human Polµ to near homogeneity (Fig.
1A). The identity of human Polµ was
confirmed by Western blot analysis using a mouse monoclonal antibody
specific to the His6 tag at its N terminus (Fig.
1B). The purified human Polµ migrated as a 60-kDa protein on a sodium dodecyl sulfate (SDS)-10% polyacrylamide gel (Fig. 1A and B), consistent with its calculated molecular mass of 55 kDa.
Separately, we deleted the C-terminal 83 amino acids of human Polµ by
gene deletion. Since the mutant protein (PolµC83) lacks several
conserved amino acid residues that are known to be critical for Pol
activity (2, 8), PolµC83 is expected to lose the
polymerase activity. Using the same vector and under conditions
identical to those with the wild-type human Polµ, the
His6-tagged PolµC83 mutant protein was
expressed in yeast cells and partially purified by an affinity Ni
column. As indicated by Western blot analysis using the monoclonal
antibody against the His6 tag, the PolµC83
protein migrated as a 48-kDa protein on an SDS-10% polyacrylamide gel (Fig. 1C), consistent with its calculated molecular mass of 45 kDa.
Using similar amounts (as estimated from a Western blot analysis) of
the Ni column fractions of Polµ and PolµC83, a DNA polymerase activity was readily detected with the wild-type Polµ (Fig. 1D, lane
1) but was undetectable with the PolµC8 mutant (Fig. 1D, lane 2).
These results show that the DNA polymerase activity being studied is
intrinsic to the purified human Polµ rather than a contaminant DNA
polymerase from yeast.
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FIG. 1.
Analysis of purified human Polµ. (A) Purified human
Polµ (300 ng) was analyzed by electrophoresis on an SDS-10%
polyacrylamide gel and visualized by silver staining. Protein mass
markers (lane M) are indicated on the left. (B) Purified human Polµ
(300 ng) was analyzed by Western blotting using a mouse monoclonal
antibody against the N-terminal His6 tag. (C) The mutant
human Polµ (PolµC83) was partially purified on a Ni column, and
the sample (700 ng) was analyzed by Western blotting using the mouse
monoclonal antibody against the N-terminal His6 tag. (D)
The Ni column fractions containing similar amounts of human Polµ and
PolµC83 as determined by a Western blot analysis were assayed for
DNA polymerase activity, using the template
5'-GGATGGACTGCAGGATCCGGAGGCCGCGCG annealed with the 5'
32P-labeled primer 5'-CGCGCGGCCTCCGGATC. The
PolµC83 sample contained 70 ng of total proteins in the polymerase
assay. DNA size markers in nucleotides are indicated on the left.
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|
Human Polµ is a distributive polymerase that lacks a 3' 
5'
proofreading exonuclease activity.
In a standard DNA polymerase
assay, purified human Polµ extended the
32P-labeled 16-mer primer by 1 nucleotide in 2 min. With increasing reaction time, longer DNA strands were synthesized
(Fig. 2A). However, DNA synthesis largely
stopped after polymerizing only 6 nucleotides in 60 min (Fig. 2A, lane
6). When human Polµ was increased by 20-fold (10-fold molar excess
over the template), only 9 nucleotides were polymerized in 10 min (data
not shown). Thus, human Polµ is a distributive polymerase and is
capable of only short-stretch DNA synthesis. To examine the 3' 5'
proofreading exonuclease activity, we incubated human Polµ with two
DNA templates containing either a matched or a mismatched base pair at
the primer 3' end (Fig. 2B). While the proofreading exonuclease
activity of the Klenow fragment of E. coli DNA polymerase I
was readily detected (Fig. 2B, lanes 2 and 5), human Polµ did not
degrade either the matched or the mismatched primers (Fig. 2B, lanes 3 and 6). These results show that human Polµ does not possess a 3' 5' proofreading exonuclease activity.
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FIG. 2.
Assays for distributive DNA synthesis and proofreading
exonuclease of human Polµ. (A) DNA polymerase assays were performed
with 1.5 ng (27 fmol) of human Polµ at 30°C for various times as
indicated, using a 40-mer DNA template containing a 16-mer 5'
32P-labeled (asterisk) primer as shown on the right.
(B) DNA substrates (50 fmol) containing a T-A (template-primer) pair
(lanes 1 to 3) or a T-T mismatch (lanes 4 to 6) (sequences shown on the
right) at the primer 3' end were incubated with purified human
Polµ (5 ng; 90 fmol) for 10 min at 37°C in the DNA polymerase assay
buffer without dNTPs. Similar assays were performed with the purified
Klenow fragment (1 U) of E. coli DNA polymerase I,
except that the incubation time was reduced to 2 min. The reaction
products were separated by electrophoresis on a 20% denaturing
polyacrylamide gel. Lanes 1 and 4, no DNA polymerase. DNA size markers
in nucleotides are indicated on the sides.
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DNA synthesis fidelity of human Polµ.
To determine whether
the biochemical properties of human Polµ are consistent with a role
in somatic hypermutation as speculated recently (8), we
examined the DNA synthesis fidelity of this polymerase. Sequences from
the JH4-JH5 intron of the rearranged human JH gene were chosen for
analyzing Polµ fidelity such that the results could be compared with
the reported hypermutation spectrum (18). DNA polymerase
assays with purified human Polµ were performed in the presence of
only one dNTP, using templates A, C, T, and G (Fig.
3A). Except for some G incorporation with the template A substrate (Fig. 3B, Temp A, lane 5), misincorporation by
human Polµ was not detectable in these sequence contexts (Fig. 3B).
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FIG. 3.
Fidelity of human Polµ. (A) Sequences from the JH4-JH5
intron of the rearranged human JH gene were used as DNA templates for
polymerase assays; the analyzed template bases are underlined. Each
primer was labeled at its 5' end with 32P as indicated by
an asterisk. (B) Polymerase assays were performed with 50 fmol of DNA
and 1.5 ng (27 fmol) of human Polµ in the presence of a single dNTP
(dATP [A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs
(N4) as indicated. DNA size markers in nucleotides are
indicated on the left.
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To quantitatively measure DNA synthesis fidelity, we performed
steady-state kinetic analyses of nucleotide incorporation by human
Polµ, using a method described by Creighton et al. (6). DNA polymerase assays were performed with increasing concentrations of
a single dNTP using 14 fmol of purified human Polµ and 50 fmol of the
primed templates A, C, T, and G (Fig. 3A), respectively. Four kinetic
parameters were obtained: Vmax,
Km,
Vmax/Km,
and finc (Table
1). As indicated by the
Vmax/Km
values, human Polµ activity is most efficient opposite template C and
much less efficient opposite the other three template bases
(Table 1). The fidelity of nucleotide incorporation is indicated
by the
(Vmax/Km)incorrect/(Vmax/Km)correct values (finc) (6). Except for
G incorporation with the template A substrate, the misincorporation
error rates (finc) of human Polµ were
not exceptionally high (Table 1) compared to those of human DNA
polymerases , , and (14, 15, 19, 23, 28, 38,
39). Furthermore, the Polµ specificity of misincorporations at
the examined A, C, T, and G sites were generally inconsistent with the
reported hypermutation specificity at the corresponding sites of the
human JH4-JH5 intron (18).
To further examine whether human Polµ is indeed prone to G
misincorporation opposite template A, we performed the analysis again
with a different template,
3'-GCCGGAGGCCAATCATACAAGCTTAC-5' (the analyzed
template A is underlined). In this sequence context, G, A, or C
incorporations were not detected (data not shown). This and other
experiments (see below) led us to infer that the G incorporation with
the template A substrate shown in Fig. 3B is probably a result of 1
frameshift DNA synthesis opposite template C 2 nucleotides downstream
rather than misincorporation opposite template A.
Frequent frameshift DNA synthesis by human Polµ.
We
consistently observed that the DNA synthesis fidelity and nucleotide
incorporation specificity of human Polµ were strongly influenced by
the sequence context, with the single-nucleotide repeat sequences
having the most dramatic effect. These observations led us to suspect
that human Polµ may be especially prone to frameshift DNA synthesis
in many sequence contexts. To directly examine this possibility,
we analyzed DNA synthesis by human Polµ from template GG, TT, AA, and
CC sequences.
A labeled 17-mer primer was annealed to the template GG, in which the
primer 3' end was paired to the 3' G of the GG sequence (Fig.
4A and B). Normal DNA synthesis would
lead to C incorporation, as observed with Pol-catalyzed DNA
synthesis (Fig. 4A, lanes 1 to 5). Misaligning the primer 3' C to the
next template G would result in T incorporation and 1 frameshift DNA
synthesis. As shown in Fig. 4A (lanes 6 to 10), human Polµ
predominantly incorporated T. With higher Polµ concentration and
extended incubation time, longer DNA strands were synthesized by human
Polµ (Fig. 4B, lane 3), allowing us to examine the synthesis products
by PstI restriction digestion. Normal DNA synthesis would
yield a 22-mer 32P-labeled DNA fragment after the
PstI cleavage, as was observed with human Pol-catalyzed
DNA synthesis (Fig. 4B, lane 2). With Polµ-catalyzed DNA synthesis,
the PstI cleavage yielded a major 21-mer DNA fragment (Fig.
4B, lane 4). These results demonstrate that DNA synthesis by human
Polµ at the examined template GG sequence is mediated predominantly
by a 1 frameshift mechanism.
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FIG. 4.
Frameshift DNA synthesis at the template GG sequence by
human Polµ. (A) Using the indicated DNA substrate, standard DNA
polymerase assays were performed with human Pol (23 ng; 605 fmol) or
human Polµ (1.5 ng; 27 fmol) in the presence of a single dNTP (dATP
[A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs
(N4) as indicated. (B) Polymerase assays were performed at
37°C for 30 min, using human Pol (23 ng; 605 fmol) or human Polµ
(30 ng; 540 fmol) as indicated. After the polymerase reaction, 5 µl
of the reaction products was mixed with 2 µl of H2O, 1 µl of the 10× PstI buffer (500 mM Tris-HCl, pH 8.0, 100 mM MgCl2, and 500 mM NaCl), and 2 µl of
PstI (20 U). After incubation at 37°C for 4 h,
the digested products were separated by electrophoresis on a 20%
denaturing polyacrylamide gel and visualized by autoradiography.
Samples without () or with (+) PstI treatment are
indicated. Underline, PstI recognition sequence; arrows,
PstI cleavage sites. (C) Using single-stranded M13mp18
containing a 17-mer 5' 32P-labeled (asterisk) primer, DNA
polymerase assays were performed with human Pol (23 ng; 605 fmol) or
human Polµ (7.5 ng; 135 fmol) at 30°C for 10 min in the presence of
a single dNTP or all four dNTPs as indicated. The analyzed template GG
sequence is underlined. DNA size markers in nucleotides are indicated
on the sides.
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To determine whether this surprising result reflects an artificially
short DNA template, which may be structurally more flexible, or
reflects an intrinsic biochemical property of human Polµ, we performed DNA synthesis at the GG sequence using single-stranded M13mp18 circular DNA (7,249 bases) as the DNA template (Fig. 4C). As
expected, human Pol incorporated a C opposite the 5' G of the GG
sequence (Fig. 4C, lanes 1 to 5). In contrast, 1 frameshift DNA
synthesis would incorporate an A opposite the template T 5' to the GG
sequence (Fig. 4C). Again, human Polµ most frequently incorporated an
A (53% primer extension) and less frequently incorporated the correct
C (39% primer extension) (Fig. 4C, lanes 6 to 10), indicating that DNA
synthesis at the template GG sequence was mediated mainly by a 1
frameshift mechanism. In the presence of all four dNTPs (Fig. 4C, lane
6), nucleotide sequence synthesized by human Polµ is consistent with
5'-AGTG (the 1 deletion product), based on the migration pattern of
the DNA bands (mobility from fastest to slowest, C>A>T>G).
Therefore, we conclude that the unprecedentedly high frequency of 1
frameshift DNA synthesis at the template GG sequence is an intrinsic
property of human Polµ.
At the template TT sequence (Fig. 5),
human Pol incorporated an A opposite the 5' T, as expected for
normal DNA synthesis (Fig. 5A, lanes 1 to 5). The 1 frameshift DNA
synthesis would lead to T incorporation opposite the template A 5' to
the TT sequence (Fig. 5). As shown in Fig. 5A (lanes 6 to 10), human
Polµ predominantly incorporated T. Remarkably, the correct A
incorporation by human Polµ had become barely detectable (Fig. 5A,
lane 7). Cleavage of the synthesized DNA products by SphI
restriction endonuclease would yield a
32P-labeled 24-mer DNA fragment, as was observed
with human Pol-catalyzed DNA synthesis (Fig. 5B, lane 2). With
Polµ-catalyzed DNA synthesis, the SphI cleavage yielded a
major 23-mer DNA fragment (Fig. 5B, lane 4). Polµ-synthesized
products were less efficiently cleaved by SphI (Fig. 5B,
compare lanes 2 and 4), probably due to shorter DNA strands and/or the
1-nucleotide loop on the template strand. These results show that DNA
synthesis by human Polµ at the examined template TT sequence is
mediated predominantly by a 1 frameshift mechanism.
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FIG. 5.
Frameshift DNA synthesis at the template TT sequence by
human Polµ. (A) Using the indicated DNA substrate, standard DNA
polymerase assays were performed with human Pol (23 ng; 605 fmol) or
human Polµ (1.5 ng; 27 fmol) in the presence of a single dNTP (dATP
[A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs
(N4) as indicated. (B) Polymerase assays were performed at
37°C for 30 min, using human Pol (23 ng; 605 fmol) or human Polµ
(30 ng; 540 fmol) as indicated. After the polymerase reaction, 5 µl
of the reaction products was mixed with 2 µl of H2O, 1 µl of the 10× SphI buffer (100 mM Tris-HCl, pH 7.9, 100 mM MgCl2, 500 mM NaCl, and 10 mM dithiothreitol), and 2 µl of SphI (10 U). After incubation at 37°C for
4 h, the digested products were separated by electrophoresis on a
20% denaturing polyacrylamide gel. Samples without () or with (+)
SphI treatment are indicated. DNA size markers in
nucleotides are indicated on the left. Asterisk, 32P label.
Underline, SphI recognition sequence; arrows,
SphI cleavage sites.
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At the template AA sequence (Fig. 6),
human Pol incorporated a T opposite the 5' A, as expected for normal
DNA synthesis (Fig. 6A, lanes 1 to 5). The 1 frameshift DNA synthesis
would lead to C incorporation opposite the template G 5' to the AA
sequence (Fig. 6). As shown in Fig. 6A (lanes 6 to 10), human Polµ
most frequently incorporated C. Less frequently, A could also be
incorporated by human Polµ (Fig. 6B, lane 7), which most likely
resulted from 2 frameshift DNA synthesis by using the template T 3 nucleotides downstream of the primer 3' end. Cleavage of the
Pol-synthesized products with NlaIII restriction
endonuclease yielded a major 22-mer DNA band (Fig. 6B, lane 2), as
expected for normal DNA synthesis. In contrast, identical treatment of
the Polµ-synthesized products with NlaIII yielded a major
21-mer DNA band (Fig. 6B, lane 4). The less efficient cleavage of
Polµ-synthesized products by NlaIII (Fig. 6B, compare
lanes 2 and 4) was probably due to shorter DNA strands; the
1-nucleotide loop on the template strand; 2 frameshift DNA synthesis,
which would destroy the NlaIII recognition site; or
combinations of these factors. These results show that DNA synthesis by
human Polµ at the examined template AA sequence is mediated
predominantly by a 1 frameshift mechanism.
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FIG. 6.
Frameshift DNA synthesis at the template AA sequence by
human Polµ. (A) Using the indicated DNA substrate, standard DNA
polymerase assays were performed with human Pol (23 ng; 605 fmol) or
human Polµ (1.5 ng; 27 fmol) in the presence of a single dNTP (dATP
[A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs
(N4) as indicated. Quantitation of extended primers is
shown below the gels. (B) Polymerase assays were performed at 37°C
for 30 min, using human Pol (23 ng; 605 fmol) or human Polµ (30 ng; 540 fmol) as indicated. After the polymerase reaction, 5 µl of
the reaction products was mixed with 2 µl of H2O, 1 µl
of the 10× NlaIII buffer (200 mM Tris-acetate, pH 8.0, 100 mM MgCl2, 500 mM potassium acetate, and 10 mM
dithiothreitol), and 2 µl of NlaIII (20 U). After
incubation at 37°C for 4 h, the digested products were separated
by electrophoresis on a 20% denaturing polyacrylamide gel. Samples
without () or with (+) NlaIII treatment are indicated.
DNA size markers in nucleotides are indicated on the left. Asterisk,
32P label; underline, NlaIII recognition
sequence; arrows, NlaIII cleavage sites.
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At the template CC sequence (Fig. 7),
human Pol incorporated a G opposite the 5' C, as expected for normal
DNA synthesis (Fig. 7A, lanes 1 to 5). The 1 frameshift DNA synthesis
would lead to T incorporation opposite the template A 5' to the CC
sequence (Fig. 7). As shown in Fig. 7A (lanes 6 to 10), human Polµ
favored T incorporation over the correct G incorporation. Minor C
incorporation was also observed (Fig. 7A, lane 8), which most likely
resulted from 2 frameshift DNA synthesis by using the template G 3 nucleotides downstream of the primer 3' end. Cleavage of the
Pol-synthesized products with the PstI restriction
endonuclease yielded a major 20-mer DNA band (Fig. 7B, lane 2), as
expected for normal DNA synthesis. In contrast, following
PstI cleavage of the Polµ-synthesized products, 1.3-fold
more 19-mer DNA band than 20-mer DNA band was formed (Fig. 7B, lane 4).
PstI cleavage of Polµ-synthesized products was
significantly less efficient than that of Pol-synthesized products
(Fig. 7B, compare lanes 2 and 4). The precise cause of this difference
is not known. Possible factors include shorter DNA strands, the
1-nucleotide loop on the template strand, some 2 frameshift DNA
synthesis, or combinations of these. These results show that human
Polµ prefers 1 frameshift DNA synthesis to normal DNA synthesis at
the examined template CC sequence.
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FIG. 7.
Frameshift DNA synthesis at the template TT sequence by
human Polµ. (A) Using the indicated DNA substrate, standard DNA
polymerase assays were performed with human Pol (23 ng; 605 fmol) or
human Polµ (1.5 ng; 27 fmol) in the presence of a single dNTP (dATP
[A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs
(N4) as indicated. Quantitation of extended primers is
shown below the gels. (B) Polymerase assays were performed at 37°C
for 30 min, using human Pol (23 ng; 605 fmol) or human Polµ (30 ng; 540 fmol) as indicated. After the polymerase reaction, 5 µl of
the reaction products was treated with 20 U of PstI as
for Fig. 4B. The digested products were separated by electrophoresis on
a 20% denaturing polyacrylamide gel. Samples without () or with (+)
PstI treatment are indicated. DNA size markers in
nucleotides are indicated on the left. Asterisk, 32P label;
underlne, PstI recognition sequence; arrows, PstI
cleavage sites.
|
|
As indicated by the steady-state kinetic values (Table
2), the rate of 1 frameshift synthesis
by human Polµ was 20-, 28-, 4.7-, and 2.4-fold higher than normal DNA
synthesis at the GG, TT, AA, and CC sequences, respectively, in the
sequence contexts examined. Together, these results show that human
Polµ catalyzes highly frequent frameshift DNA synthesis, which can
predominate as the major DNA synthesis mechanism in some sequence
contexts.
Mismatch extension by human Polµ.
Without a 3' 5'
proofreading exonuclease activity, human Polµ cannot remove
mismatched nucleotides at the primer 3' end. To examine mismatch
extension activity of human Polµ, we performed primer extension
assays using the 12 possible base pair mismatches (Fig.
8A). As shown in Fig. 8B, except for G-G,
and G-T (template-primer), all other mismatches were extended by human
Polµ. T-T, A-G, C-C, and G-A mismatches were extended most
efficiently (Fig. 8B, lanes 6, 14, 20, and 26).
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FIG. 8.
Mismatch extensions by human Polµ. (A) Various primers
labeled at their 5' ends with 32P (asterisks) were annealed
to the indicated template, generating 12 possible mismatches at the
primer 3' ends. One normal T-A-matched substrate was used as the
control. The SphI recognition sequence is overlined, and the
mismatched primer 3' ends are underlined. Arrows, SphI
cleavage sites. (B) Matched and mismatched substrates were incubated
with (+) or without () human Polµ (3 ng; 54 fmol) under standard
polymerase assay conditions. DNA size markers in nucleotides are
indicated on the sides.
|
|
To identify nucleotides incorporated during mismatch extension, we
performed the extension assays again in the presence of only one dNTP.
Human Polµ incorporated G with the T-T mismatch (Fig.
9, lanes 1 to 5), C with the A-G mismatch
(Fig. 9, lanes 16 to 20), and T with the G-A mismatch (Fig. 9, lanes 31 to 35). These incorporations are precisely predicted by a 1
frameshift synthesis mechanism involving misaligning the primer 3' end
with the next complementary template base prior to DNA synthesis. Human Polµ incorporated C with the T-G mismatch (Fig. 9, lanes 6 to 10) and
T with the C-A mismatch (Fig. 9, lanes 21 to 25), which are predicted
by a 2 frameshift synthesis mechanism involving misaligning the
primer 3' end with the complementary template base 2 nucleotides
downstream prior to DNA synthesis. With the A-C mismatch, human Polµ
preferentially incorporated A (Fig. 9, lane 12) and less frequently C
(Fig. 9, lane 13), which was consistent with 2 frameshift synthesis
by misaligning the primer 3' C 2 nucleotides downstream with the
template G and 1 frameshift synthesis using the template G 2 nucleotides downstream, respectively. With the C-C mismatch, human
Polµ slightly preferred A incorporation over T incorporation,
consistent with misaligning the primer 3' C with the next template G as
the preferred event prior to DNA synthesis (1 frameshift) (Fig. 9,
lanes 26 to 30). T incorporation (Fig. 9, lane 29) was consistent with
2 frameshift DNA synthesis using the template A 3 nucleotides
downstream.
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FIG. 9.
Nucleotide incorporation during mismatch extension.
Using the mismatched DNA substrates as indicated (sequences shown in
Fig. 8A), mismatch extension was performed with 3 ng (54 fmol) of human
Polµ under standard polymerase assay conditions. The reactions were
carried out using a single dNTP (dATP [A], dCTP [C], dTTP [T], or
dGTP [G]) or all four dNTPs (N4) as indicated. DNA size
markers in nucleotides are indicated on the sides.
|
|
To test the notion that mismatch extension by human Polµ is mediated
mainly by frameshift DNA synthesis, we slightly modified the DNA
template and analyzed extensions from G-G and G-A mismatches. The
template 3'-TA-5' sequence immediately downstream of the
mismatch was replaced by 3'-CT-5' (Fig.
10A). Frameshift extension predicts that human Polµ should then be able to extend the G-G mismatch that
was refractory to extension in the original sequence context (Fig. 8),
since the primer 3' G can pair with the next template C. Furthermore, A
incorporation is predicted. As shown in Fig. 10A (lanes 1 to 5), the
G-G mismatch was indeed effectively extended by human Polµ, and A was
incorporated. In contrast, the G-A mismatch extension by human Polµ
was drastically reduced in the new sequence context (Fig. 10A, lanes 6 to 10).
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FIG. 10.
Evidence that mismatch extension by human Polµ is
mainly mediated by frameshift DNA synthesis. (A) The template sequence
of Fig. 8A was slightly modified such that the template 3'-TA-5'
immediately downstream of the G-G and G-A mismatches was replaced
by 3'-CT-5' (underlined). These mismatched DNA substrates
were analyzed for extension by 3 ng (54 fmol) of human Polµ using a
single dNTP (dATP [A], dCTP [C], dTTP [T], or dGTP [G]) or all
four dNTPs (N4) as indicated. The mismatched primer 3' and
A are underlined. Asterisk, 32P label. (B) Polymerase
assays were performed with human Polµ (30 ng; 540 fmol) at 37°C for
30 min. After the polymerase reaction, 5 µl of the reaction products
was treated with 10 U of SphI as for Fig. 5B. The
digested products were separated by electrophoresis on a 20%
denaturing polyacrylamide gel. Samples without () or with (+)
SphI treatment are indicated. DNA size markers in
nucleotides are indicated on the sides. Mismatched DNA sequences are
shown in Fig. 8A.
|
|
Similar to the paired T-A extension (Fig. 8B, lane 2), human Polµ
extended the mismatched primers by only 1 or a few nucleotides under
the reaction conditions of low enzyme concentration and short
incubation time (Fig. 8B). With higher Polµ concentration and
extended incubation time, longer DNA strands were synthesized from a
mismatched primer 3' end (Fig. 10B, lanes 1, 3, and 5), which allowed
us to analyze the Polµ-synthesized products by SphI restriction digestion. After SphI cleavage, a 20-mer
32P-labeled DNA fragment is expected for
extension without deletion. As shown in Fig. 10B (lanes 2 and 6),
SphI cleavage of the Polµ-catalyzed T-T and A-G extension
products yielded a major 19-mer DNA fragment, demonstrating 1
deletion as the major DNA product. SphI cleavage of the
Polµ-catalyzed T-G extension products yielded a major 18-mer DNA
fragment (Fig. 10B, lane 4), demonstrating 2 deletion as the major
DNA product. Together, these results show that human Polµ can
efficiently extend base mismatches by frameshift DNA synthesis.
Human Polµ promotes microhomology search and microhomology
pairing in DNA.
The unprecedented ability of human Polµ to
perform frameshift DNA synthesis led us to suspect that this polymerase
may be capable of promoting microhomology search by realigning two
strands of DNA. To test this hypothesis, we prepared a DNA template to which three 32P-labeled primers were separately
annealed. The resulting DNA substrates contained 2-, 3-, and 4-base
mismatches, respectively, at the primer 3' end (Fig.
11A). Up to 3-nucleotide microhomology was incorporated in the template DNA 2 nucleotides downstream from the
primer 3' end. Human Polµ was then incubated with the DNA substrates
under polymerase reaction conditions. If human Polµ is able to
promote homology search by realigning the template and the primer
strands of DNA, DNA synthesis is expected and C incorporation is
predicted. Indeed, DNA synthesis was observed and C was predominantly
incorporated in every case (Fig. 11A, lanes 3, 8, and 13). Minor T
incorporation was also observed with substrates containing two or three
mismatches (Fig. 11A, lanes 4 and 9), probably as a result of mismatch
extension without frameshift. Increasing mismatched bases from two to
four at the primer 3' end greatly decreased T incorporation by human
Polµ (Fig. 11A, lanes 11 to 15), suggesting more efficient
microhomology pairing with increasing mismatches at the primer 3' end.
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FIG. 11.
Microhomology search and microhomology pairing promoted
by human Polµ. (A) A DNA template was separately annealed to three
32P-labeled (asterisks) 14-mer primers as shown, forming
two, three, and four mismatches (underlined), respectively, at the
primer ends. A sequence of 2 or 3 nucleotides (boxed) that could pair
with the last 2 or 3 nucleotides of the primers was contained in the
template 2 nucleotides downstream. (B) A 32P-labeled 14-mer
primer was annealed to a template as shown, forming 4-nucleotide
mismatches at the primer 3' end (underlined). Two 3'-AC-5'
sequences located 4 and 6 nucleotides, respectively, downstream
in the template (boxed) were complementary to the last 2 nucleotides of
the primer. These DNA substrates were incubated with human Pol (23 ng; 605 fmol) or human Polµ (3 ng; 54 fmol) under standard DNA
polymerase assay conditions in the presence of a single dNTP (dATP
[A], dCTP [C], dTTP [T], or dGTP [G]) or all four dNTPs as
indicated. DNA size markers in nucleotides are indicated on the
sides.
|
|
To examine whether the mismatched primer end can pair with a
microhomologous region further downstream in the template, we modified
the template sequence such that the last 2 nucleotides (5'-TG-3') of the primer were complementary to two template
3'-AC-5' sequences located 4 and 6 nucleotides,
respectively, downstream (Fig. 11B). If microhomology pairing had
occurred at the first template 3'-AC-5' sequence 4 nucleotides away, human Polµ would incorporate a T. If
microhomology pairing had occurred at the second template
3'-AC-5' sequence 6 nucleotides away, human Polµ would incorporate a C. As predicted by such microhomology
pairings, T incorporation by human Polµ was observed (Fig. 11B,
lane 9), and less frequently, C incorporation was also observed (Fig.
11B, lane 8). A incorporation that would have resulted from primer extension without frameshift was not detected (Fig. 11B, lane 7). In
contrast, human Pol (even in greatly excessive amounts) was completely unresponsive to this DNA substrate (Fig. 11, lanes 1 to 5).
These results show that human Polµ is capable of promoting microhomology search and subsequent microhomology pairing in DNA.
| |
DISCUSSION |
To facilitate understanding of the biological function of human
DNA Polµ, we have purified this polymerase and analyzed its biochemical properties. Surprisingly, human Polµ catalyzes frameshift DNA synthesis with an unprecedentedly high frequency. The rate of
frameshift DNA synthesis is greatly dependent on the sequence context
of the template base to be copied. When the primer 3' end is
complementary to the next template base (template AA, TT, GG, and CC
sequences), human Polµ most efficiently misaligns the primer end to
the next template base prior to DNA synthesis, resulting in 1
deletion products. Remarkably, at the template AA, TT, GG, and CC
sequences examined in this study, 1 frameshift synthesis has become
the predominant mechanism of DNA synthesis by human Polµ, with rates
ranging from 2.4- to 28-fold higher than the normal DNA synthesis. When
the primer 3' end is complementary to the template base 2 nucleotides
downstream, human Polµ can often efficiently catalyze 2
primer-template misalignment prior to DNA synthesis, leading to 2
deletion (data not shown). Compared to template AA, TT, and GG
sequences, frameshift DNA synthesis opposite template CC is less
efficient, which seems to be inversely correlated to the relatively
higher catalytic efficiency of human Polµ opposite template C. We
have additionally examined DNA templates in which the primer end could
be misaligned backward to "loop out" the primer. DNA synthesis
based on such a mechanism would produce insertion products. However,
under the conditions used in this study, there was no evidence
supporting such an insertion frameshift DNA synthesis by human Polµ
(data not shown).
Recently, Dominguez et al. (8) proposed that human Polµ
might function as a DNA mutator polymerase in somatic hypermutation of
immunoglobulin genes. Extensive analyses of immunoglobulin gene
mutations have indicated that hypermutation mainly results in base
substitutions (point mutations) (4, 12). Thus, a major
hypermutation DNA polymerase must satisfy at least two biochemical requirements: (i) be highly error prone and (ii) have higher base substitution rates than frameshift DNA synthesis rates. Using DNA
sequences derived from the JH4-JH5 intron of the rearranged human JH
gene, the measured error rates of human Polµ are not exceptionally
high (Table 1). Except for G incorporation with template A, which may
result from 1 frameshift DNA synthesis, all other error rates most
likely reflect the base substitution rates of human Polµ. These error
rates suggest that human Polµ is significantly more accurate than
human DNA polymerases , , and with respect to base
substitutions during DNA synthesis (14, 15, 19, 23, 28, 38,
39). In contrast, the extraordinary ability of human Polµ to
perform frameshift DNA synthesis is unmatched by any other DNA
polymerases known. The hypermutation spectrum at the JH4-JH5 intron
sequence shows base substitution as the vast majority of mutations
(18). Among the 242 mutations observed, 1 deletion was
scored only once, although more than one single-nucleotide repeat
sequence is contained within every 10 bp of the JH4-JH5 intron
(18). Since an intron sequence was analyzed, the
hypermutation spectrum reported by Levy et al. (18) could
not have been biased by selection. Clearly, the biochemical
property of prevalent frameshift DNA synthesis has ruled out
human Polµ as a significant somatic hypermutation DNA polymerase. DNA
Pol appears to be a more likely candidate for somatic hypermutation,
as originally proposed by us (38) and by Tissier et al.
(28).
What, then, is the cellular function of human Polµ? Our biochemical
studies may provide an important clue to the answer. Human Polµ is
highly capable of realigning the primer and the template strands of
DNA. Such realignment of two DNA strands is especially prominent at a
mismatched primer end. Primer ends that contain one to four of the
mismatches examined all promote Polµ-mediated DNA strand realignment.
The result of the primer-template realignment is microhomology pairing
between the primer end and the template strand downstream. Therefore,
human Polµ is able to promote microhomology search and subsequent
microhomology pairing between the primer strand and the template strand
of DNA. Following microhomology pairing (1- to 3-base pairing), human
Polµ can extend the primer end by 1 or a few nucleotides,
consequently further stabilizing the DNA strand realignment and the
paired microhomology region. The ability of human Polµ to promote
microhomology search and microhomology pairing between the primer and
the template strands of DNA strongly suggests a function for this
polymerase in NHEJ during repair of double-strand DNA breaks. Several
proteins have been identified for NHEJ, including Ku70, Ku80,
DNA-PKcs, XRCC4, and DNA ligase IV
(25). It is believed that the Ku70-Ku80 heterodimer binds
to the DNA ends and holds the ends together (7, 25). The
XRCC4-ligase IV complex is believed to be required to ligate DNA
strands at the last step of NHEJ (7, 11, 34). A DNA polymerase has not been identified for NHEJ in higher eukaryotes, although NHEJ would conceptually require a DNA polymerase activity. We
propose that human Polµ plays an important role in NHEJ. We hypothesize that human Polµ may function to promote microhomology search and microhomology pairing during NHEJ. Subsequent DNA polymerase activity of Polµ would stabilize the microhomology pairing to prepare
the XRCC4-ligase IV complex for DNA ligation.
In addition to repairing damage-induced double-strand DNA breaks, NHEJ
is also an essential mechanism of the V(D)J recombination. V(D)J
recombination helps generate diversity of antigen-binding sites of
antibodies and T-cell receptor proteins during lymphoid cell
development. A role for Polµ in NHEJ would predict that this polymerase is important for V(D)J recombination in lymphoid cells. Ubiquitous expression of human Polµ in various tissues, including lymphoid tissues (1, 8), is consistent with a role of this polymerase in NHEJ and V(D)J recombination. Recently, Wilson and Lieber
(35) reported evidence suggesting that yeast Pol4 (Pol) is involved in NHEJ. Since yeast Pol4 appears to be more related to
human Pol and Polµ than to human Pol (1), the
results of Wilson and Lieber (35) support our model in
which Polµ functions in NHEJ. As proposed most recently by Ruiz et
al. (26), an 8-kDa domain with potential DNA-binding
activity and an N-terminal BRCT domain similar to that of the TdT in
human Polµ are consistent with a role of this polymerase in NHEJ and
V(D)J recombination.
| |
ACKNOWLEDGMENTS |
This work was supported by a New Investigator Award in Toxicology
from the Burroughs Wellcome Fund and research grant CA67978 from NIH.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 306 Health
Sciences Research Bldg., Graduate Center for Toxicology, University of
Kentucky, Lexington, KY 40536. Phone: (859) 323-5784. Fax: (859)
323-1059. E-mail: zwang{at}pop.uky.edu.
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Molecular and Cellular Biology, December 2001, p. 7995-8006, Vol. 21, No. 23
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.23.7995-8006.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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