Structural polymorphism of chromodomains in Chd1

Chromodomain from heterochromatin protein 1 and polycomb protein is known to be a lysine-methylated histone H3 tail-binding module. Chromo-helicase/ATPase DNA-binding protein 1 (CHD1) is an ATP-dependent chromatin remodeling factor, containing two tandem chromodomains. In human CHD1, both chromodomains are essential for specific binding to a K4 methylated histone H3 (H3 MeK4) peptide and are found to bind cooperatively in the crystal structure. For the budding yeast homologue, Chd1, the second but not the first chromodomain was once reported to bind to an H3 MeK4 peptide. Here, we reveal that neither the second chromodomain nor a region containing tandem chromodomains from yeast Chd1 bind to any lysine-methylated or arginine-methylated histone peptides that we examined. In addition, we examined the structures of the chromodomains from Chd1 by NMR. Although the tertiary structure of the region containing tandem chromodomains could not be obtained, the secondary structure deduced from NMR is well conserved in the tertiary structures of the corresponding first and second chromodomains determined individually by NMR. Both chromodomains of Chd1 demonstrate a structure similar to that of the corresponding part of CHD1, consisting of a three-stranded beta-sheet followed by a C-terminal alpha-helix. However, an additional helix between the first and second beta-strands, which is found in both of the first chromodomains of Chd1 and CHD1, is positioned in an entirely different manner in Chd1 and CHD1. In human CHD1 this helix forms the peptide-binding site. The amino acid sequences of the chromodomains could be well aligned on the basis of these structures. The alignment showed that yeast Chd1 lacks several key functional residues, which are responsible for specific binding to a methylated lysine residue in other chromodomains. Chd1 is likely to have no binding affinity for any H3 MeK peptide, as found in other chromodomain proteins.     

Type 1 protein phosphatase acts in opposition to IpL1 protein kinase in regulating yeast chromosome segregation.

The IPL1 gene is required for high-fidelity chromosome segregation in the budding yeast Saccharomyces cerevisiae. Conditional ipl1ts mutants missegregate chromosomes severely at 37 degrees C. Here, we report that IPL1 encodes an essential putative protein kinase whose function is required during the later part of each cell cycle. At 26 degrees C, the permissive growth temperature, ipl1 mutant cells are defective in the recovery from a transient G2/M-phase arrest caused by the antimicrotubule drug nocodazole. In an effort to identify additional gene products that participate with the Ipl1 protein kinase in regulating chromosome segregation in yeast, a truncated version of the previously identified DIS2S1/GLC7 gene was isolated as a dosage-dependent suppressor of ipl1ts mutations. DIS2S1/GLC7 is predicted to encode a catalytic subunit (PP1C) of type 1 protein phosphatase. Overexpression of the full-length DIS2S1/GLC7 gene results in chromosome missegregation in wild-type cells and exacerbates the mutant phenotype in ipl1 cells. In addition, the glc7-1 mutation can partially suppress the ipl1-1 mutation. These results suggest that type 1 protein phosphatase acts in opposition to the Ipl1 protein kinase in vivo to ensure the high fidelity of chromosome segregation.     

Extranucleosomal DNA binding directs nucleosome sliding by Chd1

Chd1- and ISWI-type chromatin remodelers can sense extranucleosomal DNA and preferentially shift nucleosomes toward longer stretches of available DNA. The DNA-binding domains of these chromatin remodelers are believed to be responsible for sensing extranucleosomal DNA and are needed for robust sliding, but it is unclear how these domains contribute to directional movement of nucleosomes. Here, we show that the DNA-binding domain of Chd1 is not essential for nucleosome sliding but is critical for centering mononucleosomes on short DNA fragments. Remarkably, nucleosome centering was achieved by replacing the native DNA-binding domain of Chd1 with foreign DNA-binding domains of Escherichia coli AraC or Drosophila melanogaster engrailed. Introducing target DNA sequences recognized by the foreign domains enabled the remodelers to rapidly shift nucleosomes toward these binding sites, demonstrating that these foreign DNA-binding domains dictated the direction of sliding. Sequence-directed sliding occluded the target DNA sequences on the nucleosome enough to promote release of the remodeler. Target DNA sequences were highly stimulatory at multiple positions flanking the nucleosome and had the strongest influence when separated from the nucleosome by 23 or fewer base pairs. These results suggest that the DNA-binding domain's affinity for extranucleosomal DNA is the key determinant for the direction that Chd1 shifts the nucleosome.     

bZIP转录因子CfHac1参与调控果生刺盘孢菌的生长发育和致病力

油茶炭疽病是油茶Camellia oleifera上最重要病害之一,引起该病害的主要致病菌为果生刺盘孢菌Colletotrichum fructicola。本研究以果生刺盘孢菌bZIP类转录因子CfHac1为研究对象,研究其在果生刺盘孢菌的营养生长、产孢量、附着胞形成、致病力及耐受性等方面的生物学功能,为油茶炭疽病的防控提供理论依据。研究结果表明,果生刺盘孢菌中具有一个与灰色大角间座壳（稻瘟菌）bZIP转录因子MoHac1直系同源的基因,命名为CfHAC1。该基因全长1 627bp,编码526个氨基酸,该蛋白含有一个碱性亮氨酸链（bZIP）结构域和3个未知功能结构域。CfHAC1基因敲除突变体的菌丝生长速度显著变慢,分生孢子产量显著减少且不能正常形成附着胞,并对山梨糖醇和KCl渗透压胁迫敏感性增加;致病力测试结果表明,果生刺盘孢菌基因敲除突变体ΔCfhac1对油茶的致病力显著下降。转录因子CfHac1参与调控果生刺盘孢菌的生长、产孢、附着胞的形成、致病力以及响应外界渗透压胁迫过程。