Four mismatch repair paralogues coexist in Arabidopsis thaliana: AtMSH2, AtMSH3, AtMSH6-1 and AtMSH6-2

By using degenerate oligonucleotides based on the sequence homology between known MutS homologues, three MSH cDNAs belonging to the MSH2, MSH3 and MSH6 families, as defined in eukaryotes, have been isolated from Arabidopsis thaliana (ecotype Columbia). Genomic sequences for two of these genes (AtMSH2 and AtMSH6-2) were also isolated and determined, whereas the genomic sequence of AtMSH3 was obtained through the Arabidopsis sequencing project, as was the sequence of a second, distinct AtMSH6 homologue (AtMSH6-1). Comparative analysis of the AtMSH2 Landsberg erecta genomic sequence (reported here) and the previously described AtMSH2 Columbia allele revealed several polymorphisms, including the presence of a small, transposon-like element in the 3′ untranscribed region of the former allele. Arabidopsis is the first organism to show such divergence of two AtMSH6 genes; the divergence is strongly supported by sequence data and phylogenetic analysis. Southern analysis revealed that the three genes we have isolated exist as single copies, and genetic mapping indicated that AtMSH2 and AtMSH6-2 both reside on chromosome III. Finally, expression of these three genes could only be observed in suspensions of A. thaliana cells. Such a cell suspension divides actively after subculture, and the AtMSH genes are most strongly expressed at this stage.     

Binding of MutS mismatch repair protein to DNA containing UV photoproducts, "mismatched" opposite Watson--Crick and novel nucleotides, in different DNA sequence contexts

Mismatch-repair (MMR) systems suppress mutation via correction of DNA replication errors (base-mispairs) and responses to mutagenic DNA lesions. Selective binding of mismatched or damaged DNA by MutS-homolog proteins-bacterial MutS, eukaryotic MSH2.MSH6 (MutSalpha) and MSH2.MSH3-initiates mismatch-correction pathways and responses to lesions, and may cumulatively increase discrimination at downstream steps. MutS-homolog binding selectivity and the well-known but poorly understood effects of DNA-sequence contexts on recognition may thus be primary determinants of MMR specificity and efficiency. MMR processes that modulate UV mutagenesis might begin with selective binding by MutS homologs of "mismatched" T[CPD]T/AG and T[6--4]T/AG photoproducts, reported previously for hMutSalpha and described here for E. coli MutS protein. If MMR suppresses UV mutagenesis by acting directly on pre-mutagenic products of replicative bypass, mismatched photoproducts should be recognized in most DNA-sequence contexts. In three of four contexts tested here (three substantially different), T[CPD]T/AG was bound only slightly better by MutS than was T[CPD]T/AA or homoduplex DNA; only one of two contexts tested promoted selective binding of T[6--4]T/AG. Although the T:G pairs in T[CPD]T/AG and T/G both adopt wobble conformations, MutS bound T/G well in all contexts (K(1/2) 2.1--2.9 nM). Thus, MutS appears to select the two mismatches by different mechanisms. NMR analyses elsewhere suggest that in the (highly distorted) T[6--4]T/AG a forked H-bond between O2 of the 3' thymine and the ring 1-imino and exocyclic 2-amino guanine protons stabilizes a novel planar structure not possible in T[6--4]T/AA. Replacement of G by purines lacking one (inosine, 2-aminopurine) or both (nebularine) protons markedly reduced or eliminated selective MutS binding, as predicted. Previous studies and the work here, taken together, suggest that in only about half of DNA sequence contexts could MutS (and presumably MutSalpha) selectively bind mismatched UV photoproducts and directly suppress UV mutagenesis.     

DNA binding and protein-protein interaction sites in MutS, a mismatched DNA recognition protein from Thermus thermophilus HB8

The mismatch repair system repairs mismatched base pairs, which are caused by either DNA replication errors, DNA damage, or genetic recombination. Mismatch repair begins with the recognition of mismatched base pairs in DNA by MutS. Protein denaturation and limited proteolysis experiments suggest that Thermus thermophilus MutS can be divided into three structural domains as follows: A (N-terminal domain), B (central domain), and C (C-terminal domain) (Tachiki, H., Kato, R., Masui, R., Hasegawa, K., Itakura, H., Fukuyama, K., and Kuramitsu, S. (1998) Nucleic Acids Res. 26, 4153-4159). To investigate the functions of each domain in detail, truncated genes corresponding to the domains were designed. The gene products were overproduced in Escherichia coli, purified, and assayed for various activities. The MutS-MutS protein interaction site was determined by size-exclusion chromatography to be located in the B domain. The B domain was also found to possess nonspecific double-stranded DNA-binding ability. The C domain, which contains a Walker's A-type nucleotide-binding motif, demonstrated ATPase activity and specific DNA recognition of mismatched base pairs. These ATPase and specific DNA binding activities were found to be dependent upon C domain dimerization.     

Monoclonal antibody 7H6 reacts with a novel tight junction-associated protein distinct from ZO-1, cingulin and ZO-2

The tight junction is an essential element of the intercellular junctional complex; yet its protein composition is not fully understood. At present, only three proteins, ZO-1 (Stevenson, B. R., J. D. Siliciano, M. S. Mooseker, and D. A. Goodenough. 1986. J. Cell Biol. 103:755-766), cingulin (Citi, S., H. Sabanay, R. Jakes, B. Geiger, and J. Kendrick-Jones. 1988. Nature (Lond.). 333:272-275) and ZO-2 (Gumbiner, B., T. Lowenkopf, and D. Apatira. 1991. Proc. Natl. Acad. Sci. USA. 88:3460-3464) are known to be associated with the tight junction. We have generated a monoclonal antibody (7H6) against a bile canaliculus-rich membrane fraction prepared from rat liver. This 7H6 antigen was preferentially localized by immunofluorescence at the junctional complex regions of hepatocytes and other epithelia, and 7H6- affiliated gold particles were shown electron microscopically to localize at the periphery of tight junctions. Immunoblot analysis of a bile canaliculus-rich fraction of rat liver using 7H6, anti-ZO-1 antibody (R26.4C), and anti-cingulin antibody revealed that 7H6 reacted selectively with a 155-kD protein, whereas R26.4C reacted only with a 225-kD protein. Anti-cingulin antibody reacted solely with 140 and 108- kD proteins, indicating that the protein recognized by 7H6 is immunologically different from ZO-1 and cingulin. Immunoprecipitation of detergent extracts obtained from metabolically labeled MDCK cells with R26.4C coprecipitated a 160-kD protein, which corresponds to ZO-2, with ZO-1. However, 7H6 did not react with the 160-kD protein. These results strongly suggest that the 7H6 antibody recognizes a novel tight junction-associated protein different from ZO-1, cingulin and ZO-2.     

Establishment of distinct MyoD, E2A, and twist DNA binding specificities by different basic region-DNA conformations

Basic helix-loop-helix (bHLH) proteins perform a wide variety of biological functions. Most bHLH proteins recognize the consensus DNA sequence CAN NTG (the E-box consensus sequence is underlined) but acquire further functional specificity by preferring distinct internal and flanking bases. In addition, induction of myogenesis by MyoD-related bHLH proteins depends on myogenic basic region (BR) and BR-HLH junction residues that are not essential for binding to a muscle-specific site, implying that their BRs may be involved in other critical interactions. We have investigated whether the myogenic residues influence DNA sequence recognition and how MyoD, Twist, and their E2A partner proteins prefer distinct CAN NTG sites. In MyoD, the myogenic BR residues establish specificity for particular CAN NTG sites indirectly, by influencing the conformation through which the BR helix binds DNA. An analysis of DNA binding by BR and junction mutants suggests that an appropriate BR-DNA conformation is necessary but not sufficient for myogenesis, supporting the model that additional interactions with this region are important. The sequence specificities of E2A and Twist proteins require the corresponding BR residues. In addition, mechanisms that position the BR allow E2A to prefer distinct half-sites as a heterodimer with MyoD or Twist, indicating that the E2A BR can be directed toward different targets by dimerization with different partners. Our findings indicate that E2A and its partner bHLH proteins bind to CAN NTG sites by adopting particular preferred BR-DNA conformations, from which they derive differences in sequence recognition that can be important for functional specificity.     

Specific binding of human MSH2.MSH6 mismatch-repair protein heterodimers to DNA incorporating thymine- or uracil-containing UV light photoproducts opposite mismatched bases.

Previous studies have demonstrated recognition of DNA-containing UV light photoproducts by bacterial (Feng, W.-Y., Lee, E., and Hays, J. B. (1991) Genetics 129, 1007-1020) and human (Mu, D., Tursun, M., Duckett, D. R., Drummond, J. T., Modrich, P., and Sancar, A. (1997) Mol. Cell. Biol. 17, 760-769) long-patch mismatch-repair systems. Mismatch repair directed specifically against incorrect bases inserted during semi-conservative DNA replication might efficiently antagonize UV mutagenesis. To test this hypothesis, DNA 51-mers containing site-specific T-T cis-syn-cyclobutane pyrimidine-dimers or T-T pyrimidine-(6-4')pyrimidinone photoproducts, with all four possible bases opposite the respective 3'-thymines in the photoproducts, were analyzed for the ability to compete with radiolabeled (T/G)-mismatched DNA for binding by highly purified human MSH2.MSH6 heterodimer protein (hMutSalpha). Both (cyclobutane-dimer)/AG and ((6-4)photoproduct)/AG mismatches competed about as well as non-photoproduct T/T mismatches. The two respective pairs of photoproduct/(A(T or C)) mismatches also showed higher hMutSalpha affinity than photoproduct/AA "matches"; the apparent affinity of hMutSalpha for the ((6-4)photoproduct)/AA-"matched" substrate was actually less than that for TT/AA homoduplexes. Surprisingly, although hMutSalpha affinities for both non-photoproduct UU/GG double mismatches and for (uracil-cyclobutane-dimer)/AG single mismatches were high, affinity for the (uracil-cyclobutane-dimer)/GG mismatch was quite low. Equilibrium binding of hMutSalpha to DNA containing (photoproduct/base) mismatches and to (T/G)-mismatched DNA was reduced similarly by ATP (in the absence of magnesium).     

Arabidopsis AtcwINV3 and 6 are not invertases but are fructan exohydrolases (FEHs) with different substrate specificities

The genome of Arabidopsis thaliana contains six putative cell-wall type invertase genes (AtcwINV1-6). Heterologous expression of AtcwINV1, 3 and 6 cDNAs in Pichia pastoris revealed that the enzymes encoded by AtcwINV3 and 6 did not show invertase activity. Instead, AtcwINV3 is a 6-FEH and AtcwINV6 is a fructan exohydrolase (FEH) that can degrade both inulin and levan-type fructans. For AtcwINV6 it is proposed to use the term (6&1) FEH. In contrast, AtcwINV1 is a typical invertase. FEH activity was also detected in crude extracts of different parts of Arabidopsis. To verify that the FEH activity of AtcwINV3 and 6 were not artefacts of the heterologous expression system, the protein corresponding to AtcwINV3 was isolated from whole Arabidopsis plants and indeed showed only 6-FEH activity and no invertase activity. Although no fructans can be detected in Arabidopsis plants, it is shown that kestoses (trimers) can be synthesized in crude leaf extracts. The putative physiological significance of FEH in so-called non-fructan plants is discussed.     

Identification of a novel small Arabidopsis protein interacting with gamma-tubulin complex protein 3

In higher plants, microtubules (MTs) show dynamic structural changes during cell cycle and development progression. A precise control of MT nucleation at dispersed sites is one way used to regulate the cytoskeletal organization. Some gamma-tubulin complex proteins (GCPs) were previously identified in Arabidopsis thaliana (At). They are directly involved in the nucleation process. Nevertheless, no additional player which may anchor the nucleating complex or regulate the nucleation activity has been found in plant cells so far. Therefore, our aim was the identification of Arabidopsis proteins interacting with MT nucleating complexes and particularly with AtGCP3. Performing a yeast two-hybrid screen, we discovered a new protein which we called AtGCP3 Interacting Protein 1 (AtGIP1). The possible role of this protein during the nucleation process is discussed.     

Four mismatch repair paralogues coexist in Arabidopsis thaliana : AtMSH2, AtMSH3, AtMSH6-1 and AtMSH6-2

By using degenerate oligonucleotides based on the sequence homology between known MutS homologues, three MSH cDNAs belonging to the MSH2, MSH3 and MSH6 families, as defined in eukaryotes, have been isolated from Arabidopsis thaliana (ecotype Columbia). Genomic sequences for two of these genes (AtMSH2 and AtMSH6-2) were also isolated and determined, whereas the genomic sequence of AtMSH3 was obtained through the Arabidopsis sequencing project, as was the sequence of a second, distinct AtMSH6 homologue (AtMSH6-1). Comparative analysis of the AtMSH2 Landsberg erecta genomic sequence (reported here) and the previously described AtMSH2 Columbia allele revealed several polymorphisms, including the presence of a small, transposon-like element in the 3′ untranscribed region of the former allele. Arabidopsis is the first organism to show such divergence of two AtMSH6 genes; the divergence is strongly supported by sequence data and phylogenetic analysis. Southern analysis revealed that the three genes we have isolated exist as single copies, and genetic mapping indicated that AtMSH2 and AtMSH6-2 both reside on chromosome III. Finally, expression of these three genes could only be observed in suspensions of A. thaliana cells. Such a cell suspension divides actively after subculture, and the AtMSH genes are most strongly expressed at this stage. Received: 23 February 1999 / Accepted: 5 May 1999     

Diversity of N-acetylglucosamine-6-O-sulfotransferases: molecular cloning of a novel enzyme with different distribution and specificities

N-Acetylglucosamine-6-O-sulfotransferase (GlcNAc6ST) transfers sulfate to the C-6 position of non-reducing N-acetylglucosamine (GlcNAc) residues. We cloned human and mouse cDNAs encoding a novel GlcNAc6ST, designated as GlcNAc6ST-4, which showed sequence identities of 26 to 41% to other GlcNAc6STs. Human organs with strong expression of the enzyme mRNA were the heart, spleen, and ovary, while in the mouse strong expression was detected in the kidney. The enzyme expressed in CHO cells preferentially acted on mannose-linked GlcNAc, while a core 2 mucin-type oligosaccharide and an N-acetyllactosamine oligomer also served as acceptors. The distribution and the specificity of GlcNAc6ST are different from those of GlcNAc6STs identified previously.     

Human MutY homolog, a DNA glycosylase involved in base excision repair, physically and functionally interacts with mismatch repair proteins human MutS homolog 2/human MutS homolog 6.

Adenines mismatched with guanines or 7,8-dihydro-8-oxo-deoxyguanines that arise through DNA replication errors can be repaired by either base excision repair or mismatch repair. The human MutY homolog (hMYH), a DNA glycosylase, removes adenines from these mismatches. Human MutS homologs, hMSH2/hMSH6 (hMutSalpha), bind to the mismatches and initiate the repair on the daughter DNA strands. Human MYH is physically associated with hMSH2/hMSH6 via the hMSH6 subunit. The interaction of hMutSalpha and hMYH is not observed in several mismatch repair-defective cell lines. The hMutSalpha binding site is mapped to amino acid residues 232-254 of hMYH, a region conserved in the MutY family. Moreover, the binding and glycosylase activities of hMYH with an A/7,8-dihydro-8-oxo-deoxyguanine mismatch are enhanced by hMutSalpha. These results suggest that protein-protein interactions may be a means by which hMYH repair and mismatch repair cooperate in reducing replicative errors caused by oxidized bases.     

Human paraoxonases (PON1, PON2, and PON3) are lactonases with overlapping and distinct substrate specificities

The paraoxonase (PON) gene family in humans has three members, PON1, PON2, and PON3. Their physiological role(s) and natural substrates are uncertain. We developed a baculovirus-mediated expression system, suitable for all three human PONs, and optimized procedures for their purification. The recombinant PONs are glycosylated with high-mannose-type sugars, which are important for protein stability but are not essential for their enzymatic activities. Enzymatic characterization of the purified PONs has revealed them to be lactonases/lactonizing enzymes, with some overlapping substrates (e.g., aromatic lactones), but also to have distinctive substrate specificities. All three PONs metabolized very efficiently 5-hydroxy-eicosatetraenoic acid 1,5-lactone and 4-hydroxy-docosahexaenoic acid, which are products of both enzymatic and nonenzymatic oxidation of arachidonic acid and docosahexaenoic acid, respectively, and may represent the PONs' endogenous substrates. Organophosphates are hydrolyzed almost exclusively by PON1, whereas bulky drug substrates such as lovastatin and spironolactone are hydrolyzed only by PON3. Of special interest is the ability of the human PONs, especially PON2, to hydrolyze and thereby inactivate N-acyl-homoserine lactones, which are quorum-sensing signals of pathogenic bacteria. None of the recombinant PONs protected low density lipoprotein against copper-induced oxidation in vitro.     

DNA mismatch repair in plants. An Arabidopsis thaliana gene that predicts a protein belonging to the MSH2 subfamily of eukaryotic MutS homologs.

Sets of degenerate oligomers corresponding to highly conserved domains of MutS-homolog (MSH) mismatch-repair proteins primed polymerase chain reaction amplification of two Arabidopsis thaliana DNA fragments that are homologous to eukaryotic MSH-like genes. Phylogenetic analysis places one complete gene, designated atMSH2, in the evolutionarily distinct MSH2 subfamily.     

Rabring7, a novel Rab7 target protein with a RING finger motif

Rab7, a member of the Rab family small G proteins, has been shown to regulate intracellular vesicle traffic to late endosome/lysosome and lysosome biogenesis, but the exact roles of Rab7 are still undetermined. Accumulating evidence suggests that each Rab protein has multiple target proteins that function in the exocytic/endocytic pathway. We have isolated a new Rab7 target protein, Rabring7 (Rab7-interacting RING finger protein), using a CytoTrap system. It contains an H2 type RING finger motif at the C termini. Rabring7 shows no homology with RILP, which has been reported as another Rab7 target protein. GST pull-down and coimmunoprecipitation assays demonstrate that Rabring7 specifically binds the GTP-bound form of Rab7 at the N-terminal portion. Rabring7 is found mainly in the cytosol and is recruited efficiently to late endosomes/lysosomes by the GTP-bound form of Rab7 in BHK cells. Overexpression of Rabring7 not only affects epidermal growth factor degradation but also causes the perinuclear aggregation of lysosomes, in which the accumulation of the acidotropic probe LysoTracker is remarkably enhanced. These results suggest that Rabring7 plays crucial roles as a Rab7 target protein in vesicle traffic to late endosome/lysosome and lysosome biogenesis.     

PR48, a novel regulatory subunit of protein phosphatase 2A, interacts with Cdc6 and modulates DNA replication in human cells

Initiation of DNA replication in eukaryotes is dependent on the activity of protein phosphatase 2A (PP2A), but specific phosphoprotein substrates pertinent to this requirement have not been identified. A novel regulatory subunit of PP2A, termed PR48, was identified by a yeast two-hybrid screen of a human placental cDNA library, using human Cdc6, an essential component of prereplicative complexes, as bait. PR48 binds specifically to an amino-terminal segment of Cdc6 and forms functional holoenzyme complexes with A and C subunits of PP2A. PR48 localizes to the nucleus of mammalian cells, and its forced overexpression perturbs cell cycle progression, causing a G(1) arrest. These results suggest that dephosphorylation of Cdc6 by PP2A, mediated by a specific interaction with PR48, is a regulatory event controlling initiation of DNA replication in mammalian cells.