doi: 10.1093/nar/29.8.1695.
The interacting domains of three MutL heterodimers in man: hMLH1 interacts with 36 homologous amino acid residues within hMLH3, hPMS1 and hPMS2
Affiliations
- PMID: 11292842
- PMCID: PMC31313
- DOI: 10.1093/nar/29.8.1695
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The interacting domains of three MutL heterodimers in man: hMLH1 interacts with 36 homologous amino acid residues within hMLH3, hPMS1 and hPMS2
Nucleic Acids Res.
.
Abstract
In human cells, hMLH1, hMLH3, hPMS1 and hPMS2 are four recognised and distinctive homologues of MutL, an essential component of the bacterial DNA mismatch repair (MMR) system. The hMLH1 protein forms three different heterodimers with one of the other MutL homologues. As a first step towards functional analysis of these molecules, we determined the interacting domains of each heterodimer and tried to understand their common features. Using a yeast two-hybrid assay, we show that these MutL homologues can form heterodimers by interacting with the same amino acid residues of hMLH1, residues 492-742. In contrast, three hMLH1 partners, hMLH3, hPMS1 and hPMS2 contain the 36 homologous amino acid residues that interact strongly with hMLH1. Contrary to the previous studies, these homologous residues reside at the N-terminal regions of three subdomains conserved in MutL homologues in many species. Interestingly, these residues in hPMS2 and hMLH3 may form coiled-coil structures as predicted by the MULTICOIL program. Furthermore, we show that there is competition for the interacting domain in hMLH1 among the three other MutL homologues. Therefore, the quantitative balance of these three MutL heterodimers may be important in their functions.
Figures
Domains of hMLH1 interacting
with hMLH3, hPMS1 and hPMS2. The β-gal
activities in yeast cells containing various lexA DNA BD and VP16
transcriptional AD plasmids. The left figure represents schematic
diagrams of the full-length (residues 1–756) and the 15 hMLH1 deletion constructs in AD plasmids. Lane
hMLH3, hPMS1 or hPMS2 indicates the β-gal
activities of yeast cells that contain the full-length hMLH3, hPMS1 or hPMS2 BD plasmid and
the corresponding truncated hMLH1 AD plasmid. The
mean and SD of three independent transformants are shown. The mean β-gal activities in yeast cells containing
only hMLH3, hPMS1 or hPMS2 BD plasmid are 0.3, 0.1 or 0.1 U, respectively.
Summary of the two-hybrid
assay, GST-IVTT and immunoprecipitation study between the full-length hMLH1 and various hPMS2 deletion
constructs. These three assays were performed as described in Materials
and Methods. The left figure represents schematic diagrams of the
full-length (residues 1–862) and the twenty-six hPMS2 deletion
constructs. The mean and SD of β-gal
activities in three independent yeast transformants containing various hPMS2 deletion constructs in the BD plasmid and
the full-length hMLH1 cDNA in the AD plasmid are
indicated in the two-hybrid lane. The values in parentheses represent
the mean β-gal activity in the yeast
cell containing only the corresponding BD plasmid. Results of the
GST-IVTT assay are presented as the mean and SD of three separate experiments
and are indicated as relative values when the binding ability of
the full-length hPMS2 to GST-hMLH1 is 100. Lane IP indicates the
presence (+) or absence (–) of the immunoprecipitated
band. ND, not detected.
Determination of the hMLH1-interactive
domain of hPMS2 at residues 612–674 using the immunoprecipitation
study (A) and the GST-IVTT assay (B). (A)
Extracts of HEC-1-A cells transfected with pFLAG plasmids containing
various hPMS2 deletion constructs were subjected
to immunoprecipitation analyses using the anti-FLAG M2 monoclonal
antibody. Immunoprecipitated proteins were analysed by the use of
anti-hMLH1 monoclonal antibody. Lane HEC-1-A illustrates 20 µg of the cell extract that was subjected
to immunoblotting without prior immunoprecipitation as the control.
The arrow indicates the position of the hMLH1 protein. The minimal
interaction domain of hPMS2 with hMLH1 lies between residues 612
and 674. (B) 35S-labeled full-length and deletion mutant
proteins of IVTT-hPMS2 were added to glutathione beads that had
been pre-treated with either GST alone (–) or GST-hMLH1
(+). Samples were resolved on 8% (top left), 15% (top
right) or 10–20% (bottom) SDS-PAGE and examined
by BAS-1500 and LAS-1000 (Fuji Film). Again the minimal interacting
domain of hPMS2 with hMLH1 resides at residues 612–674.
36 homologous amino acid
residues conserved in hPMS2, hPMS1 and hMLH3. The proportions of
identity or similarity with residues 612–674 of hPMS2 are
presented. Lowercase letters indicate positions of the heptad repeat
in the predicted coiled-coil motif. Bold letters in the consensus
sequence correspond to identical amino acids. X, non-conserved amino
acids. As for hMLH3, four homologous regions were identified, however,
only residues 860–895, the highest homologous region, can
interact with hMLH1.
Domain of hPMS1 interacting
with hMLH1. Results of the two-hybrid assay in yeast cells that
contain the corresponding hPMS1 constructs (left
figure) in the BD plasmid and the full-length hMLH1 cDNA
in the AD plasmid. Parentheses indicate the mean β-gal
activities in the yeast cells containing only the corresponding
BD plasmid. Each β-gal activity is the
mean and SD of three independent transformants. The minimal interacting
domain of hPMS1 with hMLH1 resides at residues 693–728
as established in Figure 4.
Domains
of hMLH3 interacting with hMLH1. Results of the two-hybrid assay
in yeast cells that contain the corresponding hMLH3 constructs
(left figure) in the BD plasmid and the full-length hMLH1 cDNA
in the AD plasmid. Parentheses indicate the mean β-gal
activities in the yeast cells containing only the corresponding
BD plasmid. Each β-gal activity is the
mean and SD of three independent transformants. The domain of hMLH3
interacting with hMLH1 resides at residues 860–895, as
established in Figure 4. There are two additional domains of hMLH3
interacting with hMLH1 at residues 1–244 and 1399–1453.
The structural
relationship between each interacting domain and three subdomains
in four MutL homologues: hMLH1, hPMS2, hPMS1 and hMLH3. The 36 homologous
amino acid residues showing strong interacting activities were all
located in the N-terminal regions of three MutL subdomains.
Competitive
inhibition of hPMS2 binding by hPMS1 or hMLH3 when complexed with
GST-hMLH1. The GST-hMLH1 and 2 µl of 35S-labeled
IVTT-hPMS2 were incubated with indicated amounts of unlabeled IVTT-luciferase,
IVTT-hPMS1 or IVTT-hMLH3. Then hPMS2 complexed with GST-hMLH1 was resolved
by 10–20% SDS–PAGE and examined by BAS-1500.
The arrow indicates the position of hPMS2 protein. Both hPMS1 and
hMLH3 compete with hPMS2 for the binding to hMLH1.
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References
-
- Modrich P. (1991) Mechanisms and biological effects of mismatch repair. Annu. Rev. Genet., 25, 229–253. - PubMed
-
- Kolodner R. (1996) Biochemistry and genetics of eukaryotic mismatch repair. Genes Dev., 10, 1433–1442. - PubMed
-
- Peltomäki P. and Vasen,H.F.A. (1997) Mutations predisposing to hereditary nonpolyposis colorectal cancer: database and results of a collaborative study. Gastroenterology, 113, 1146–1158. - PubMed
-
- Eshleman J.R. and Markowitz,S.D. (1995) Microsatellite instability in inherited and sporadic neoplasms. Curr. Opin. Oncol., 7, 83–89. - PubMed
-
- Modrich P. and Lahue,R. (1996) Mismatch repair in replication fidelity, genetic recombination and cancer biology. Annu. Rev. Biochem., 65, 101–133. - PubMed
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