Three Saccharomyces cerevisiae proteins (Yng1/YOR064c, Yng2/YHR090c, and Pho23) and two Schizosaccharomyces pombe proteins (Png1/CAA15917 and Png2/CAA21250) share significant sequence identity with the human candidate tumor suppressor p33 ING1 in their C-terminal regions. The homologous regions contain PHD finger domains which have been implicated in chromatin-mediated transcriptional regulation. We show that GFP-Yng2, like human Ing1, is localized in the nucleus. Deletion of YNG2 results in several phenotypes, including an abnormal multibudded morphology, an inability to utilize nonfermentable carbon sources, heat shock sensitivity, slow growth, temperature sensitivity, and sensitivity to caffeine. These phenotypes are suppressed by expression of either human Ing1 or S. pombe Png1, suggesting that the yeast and human proteins are functionally conserved. Yng1-and Pho23-deficient cells also share some of these phenotypes. We demonstrated by yeast two-hybrid and coimmunoprecipitation tests that Yng2 interacts with Tra1, a component of histone acetyltransferase (HAT) complexes. We further demonstrated by coimmunoprecipitation that HAYng1, HA-Yng2, HA-Pho23, and HA-Ing1 are associated with HAT activities in yeast. Genetic and biochemical evidence indicate that the Yng2-associated HAT is Esa1, suggesting that Yng2 is a component of the NuA4 HAT complex. These studies suggest that the yeast Ing1-related proteins are involved in chromatin remodeling. They further suggest that these functions may be conserved in mammals and provide a possible mechanism for the human Ing1 candidate tumor suppressor. Several observations suggest that mammalian p33ING1 is involved in the regulation of cell proliferation and apoptosis (18,21,28). NIH 3T3 cells transformed by infection with a retrovirus containing a region of the Ing1 cDNA in the antisense orientation exhibit anchorage-independent growth in soft agar, and they form tumors in nude mice. Furthermore, microinjection of constructs that express Ing1 in the sense orientation results in inhibition of DNA synthesis and cell cycle progression in human diploid fibroblasts. Ing1 levels are also increased upon the induction of apoptosis in P19 cells by serum deprivation, and overexpression of Ing1 in P19 and rodent fibroblasts enhances Myc-dependent apoptosis (28). Evidence indicates that expression of Ing1 is repressed in a majority of breast and lymphoid cancer cell lines and glioblastomas and is mutated in some neuroblastoma cell lines, breast cancers, and brain tumors (21,52,74). Together, these observations suggest that Ing1 acts as a tumor suppressor and that it is involved in regulating apoptosis. This is further supported by reports that Ing1 and the p53 tumor suppressor form a complex and functionally cooperate to control cell growth (20, 83).The carboxyl-terminal 70 amino acid residues of Ing1 contain the Cys 4 -His-Cys 3 sequence of a PHD finger domain. This evolutionarily conserved domain is predicted to chelate two Zn 2ϩ ions and is similar to, but distinct from, other zinc...
affects the degree of physical association between proliferating cell nuclear antigen (PCNA) and p300, an association that has been proposed to link DNA repair to chromatin remodeling. Together with the finding that human ING1 proteins bind PCNA in a DNA damagedependent manner, these data suggest that ING1 proteins provide a direct linkage between DNA repair, apoptosis, and chromatin remodeling via multiple HAT⅐ING1⅐PCNA protein complexes.
We have identified, cloned, and studied a gene, cap, encoding a protein that is associated with adenylyl cyclase in the fission yeast Schizosaccharomyces pombe. This protein shares significant sequence homology with the adenylyl cyclase-associated CAP protein in the yeast Saccharomyces cerevisiae. CAP is a bifunctional protein; the N-terminal domain appears to be involved in cellular responsiveness to RAS, whereas loss of the C-terminal portion is associated with morphological and nutritional defects. S. pombe cap can suppress phenotypes associated with deletion of the C-terminal CAP domain in S. cerevisiae but does not suppress phenotypes associated with deletion of the N-terminal domain. Analysis of cap disruptants also mapped the function of cap to two domains. The functional loss of the C-terminal region of S. pombe cap results in abnormal cellular morphology, slow growth, and failure to grow at 37 degrees C. Increases in mating and sporulation were observed when the entire gene was disrupted. Overproduction of both cap and adenylyl cyclase results in highly elongated large cells that are sterile and have measurably higher levels of adenylyl cyclase activity. Our results indicate that cap is required for the proper function of S. pombe adenylyl cyclase but that the C-terminal domain of cap has other functions that are shared with the C-terminal domain of S. cerevisiae CAP.
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