Kabuki syndrome is a congenital anomaly syndrome characterized by developmental delay, intellectual disability, specific facial features including long palpebral fissures and ectropion of the lateral third of the lower eyelids, prominent digit pads, and skeletal and visceral abnormalities. Mutations in MLL2 and KDM6A cause Kabuki syndrome. We screened 81 individuals with Kabuki syndrome for mutations in these genes by conventional methods (n = 58) and/or targeted resequencing (n = 45) or whole exome sequencing (n = 5). We identified a mutation in MLL2 or KDM6A in 50 (61.7%) and 5 (6.2%) cases, respectively. Thirty-five MLL2 mutations and two KDM6A mutations were novel. Non-protein truncating-type MLL2 mutations were mainly located around functional domains, while truncating-type mutations were scattered through the entire coding region. The facial features of patients in the MLL2 truncating-type mutation group were typical based on those of the 10 originally reported patients with Kabuki syndrome; those of the other groups were less typical. High arched eyebrows, short fifth finger, and hypotonia in infancy were more frequent in the MLL2 mutation group than in the KDM6A mutation group. Short stature and postnatal growth retardation were observed in all individuals with KDM6A mutations, but in only half of the group with MLL2 mutations.
Genetic and biochemical analyses of Pfh1 DNA helicase function in fission yeast
The Schizosaccharomyces pombe pfh1+ gene (PIF1 homolog) encodes an essential enzyme that has both DNA helicase and ATPase activities and is implicated in lagging strand DNA processing. Mutations in the pfh1+ gene suppress a temperature-sensitive allele of cdc24+, which encodes a protein that functions with Schizosaccharomyces pombe Dna2 in Okazaki fragment processing. In this study, we describe the enzymatic properties of the Pfh1 helicase and the genetic interactions between pfh1 and cdc24, dna2, cdc27 or pol 3, all of which are involved in the Okazaki fragment metabolism. We show that a full-length Pfh1 fusion protein is active as a monomer. The helicase activity of Pfh1 displaced only short (<30 bp) duplex DNA regions efficiently in a highly distributive manner and was markedly stimulated by the presence of a replication-fork-like structure in the substrate. The temperature-sensitive phenotype of a dna2-C2 or a cdc24-M38 mutant was suppressed by pfh1-R20 (a cold-sensitive mutant allele of pfh1) and overexpression of wild-type pfh1+ abolished the ability of the pfh1 mutant alleles to suppress dna2-C2 and cdc24-M38. Purified Pfh1-R20 mutant protein displayed significantly reduced ATPase and helicase activities. These results indicate that the simultaneous loss-of-function mutations of pfh1+ and dna2+ (or cdc24+) are essential to restore the growth defect. Our genetic data indicate that the Pfh1 DNA helicase acts in concert with Cdc24 and Dna2 to process single-stranded DNA flaps generated in vivo by pol -mediated lagging strand displacement DNA synthesis.
The Cdc24 protein plays an essential role in chromosomal DNA replication in the fission yeast Schizosaccharomyces pombe, most likely via its direct interaction with Dna2, a conserved endonuclease-helicase protein required for Okazaki fragment processing. To gain insights into Cdc24 function, we isolated cold-sensitive chromosomal suppressors of the temperature-sensitive cdc24-M38 allele. One of the complementation groups of such suppressors defined a novel gene, pfh1(+), encoding an 805 amino acid nuclear protein highly homologous to the Saccharomyces cerevisiae Pif1p and Rrm3p DNA helicase family proteins. The purified Pfh1 protein displayed single-stranded DNA-dependent ATPase activity as well as 5' to 3' DNA helicase activity in vitro. Reverse genetic analysis in S.pombe showed that helicase activity was essential for the function of the Pfh1 protein in vivo. Schizosaccharomyces pombe cells carrying the cold-sensitive pfh1-R20 allele underwent cell cycle arrest in late S/G2-phase of the cell cycle when shifted to the restrictive temperature. This arrest was dependent upon the presence of a functional late S/G2 DNA damage checkpoint, suggesting that Pfh1 is required for the completion of DNA replication. Furthermore, at their permissive temperature pfh1-R20 cells were highly sensitive to the DNA-alkylating agent methyl methanesulphonate, implying a further role for Pfh1 in the repair of DNA damage.
At the nonpermissive temperature the fission yeast cdc24-M38 mutant arrests in the cell cycle with incomplete DNA replication as indicated by pulsed-field gel electrophoresis. The cdc24 ؉ gene encodes a 501-aminoacid protein with no significant homology to any known proteins. The temperature-sensitive cdc24 mutant is effectively rescued by pcn1 ؉ , rfc1 ؉ (a fission yeast homologue of RFC1), and hhp1 ؉ , which encode the proliferating cell nuclear antigen (PCNA), the large subunit of replication factor C (RFC), and a casein kinase I involved in DNA damage repair, respectively. The Cdc24 protein binds PCNA and RFC1 in vivo, and the domains essential for Cdc24 function and for RFC1 and PCNA binding colocalize in the N-terminal two-thirds of the molecule. In addition, cdc24؉ genetically interacts with the gene encoding the catalytic subunit of DNA polymerase , which is stimulated by PCNA and RFC, and with those encoding the fission yeast counterparts of Mcm2, Mcm4, and Mcm10. These results indicate that Cdc24 is an RFC-and PCNA-interacting factor required for DNA replication and might serve as a target for regulation.Chromosomal DNA is replicated by cooperation of a number of factors and enzymes. In the budding yeast Saccharomyces cerevisiae they include the origin recognition complex, which is composed of the six subunits called Orc1 to Orc6 (4); Cdc6 (8); minichromosome maintenance (MCM) proteins (56); and at least three DNA polymerases. The origin recognition complex recognizes and binds origins of replication throughout the cell cycle. When cells enter S phase, MCM proteins are loaded onto the origins in a Cdc6-dependent manner (2, 53), and finally DNA polymerase ␣ (Pol ␣), Pol ␦, and Pol ε are recruited to start DNA synthesis. A recent analysis indicates that not only these polymerases but also some MCM proteins are components of replication forks (2).The roles of Pol ␣, Pol ␦, and other factors in DNA replication were initially elucidated by studies with a cell-free simian virus 40 (SV40) DNA replication system (reviewed in references 51 and 58). In this system, Pol ␣ with its primase subunits synthesizes RNA primers and elongates them to short initiator DNAs, which in turn serve as primers for the leadingand lagging-strand synthesis that is catalyzed by Pol ␦. Thus, during DNA replication, the polymerase used for synthesis is switched from ␣ to ␦. This switch requires two accessory proteins, replication factor C (RFC) and proliferating cell nuclear antigen (PCNA) (55). RFC binds the primer ends and thereby recruits and loads PCNA onto them (29, 54). Subsequently, Pol ␦ binds the complex and elongates the DNA strands with high processivity (54). RFC is composed of five related subunits, one large and four small ones. By contrast, PCNA forms homotrimers to act as a sliding clamp (27). This factor is essential for the high processivity of Pol ␦ (47, 48). These polymerases and accessory proteins are highly conserved throughout eukaryotes. The replication of chromosomal DNA, however, requires another type of DNA ...
Fission yeast checkpoint protein Rad17 is required for the DNA integrity checkpoint responses. A fraction of Rad17 is chromatin bound independent of the other checkpoint proteins throughout the cell cycle. Here we show that in response to DNA damage induced by either methyl methanesulfonate treatment or ionizing radiation, increased levels of Rad17 bind to chromatin. Following S-phase stall induced by hydroxyurea or a cdc22 mutation, the chromatin-bound Rad17 progressively dissociates from the chromatin. After S-phase arrest by hydroxyurea in cds1⌬ or rad3⌬ cells or by replication mutants, Rad17 remains chromatin bound. Rad17 is able to complex in vivo with an Rfc small subunit, Rfc2, but not with Rfc1. Furthermore, cells with rfc1⌬ are checkpoint proficient, suggesting that Rfc1 does not have a role in checkpoint function. A checkpointdefective mutant protein, Rad17(K118E), which has similar nuclear localization to that of the wild type, is unable to bind ATP and has reduced ability in chromatin binding. Mutant Rad17(K118E) protein also has reduced ability to complex with Rfc2, suggesting that Lys 118 of Rad17 plays a role in Rad17-Rfc small-subunit complex formation and chromatin association. However, in the rad17.K118E mutant cells, Cds1 can be activated by hydroxyurea. Together, these results suggest that Rad17 binds to chromatin in response to an aberrant genomic structure generated from DNA damage, replication mutant arrest, or hydroxyurea arrest in the absence of Cds1. Rad17 is not required to bind chromatin when genomic structures are protected by hydroxyurea-activated Cds1. The possible checkpoint events induced by chromatin-bound Rad17 are discussed.
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