Recombinant AtNF-YA, a subunit of theArabidopsis CCAAT-binding transcription factor, forms a protein-DNA complex with mammalian NF-YB and NF-YC

The evolutionary conserved CCAAT binding protein NF-Y is a common regulatory DNA binding protein consisting of three distinct subunits. Unlike yeast and mammals, in which only a single copy of each subunit is encoded,Arabidopsis encodes a multi-gene family for each subunit in its genome. Compared with the NF-Y of mammals or yeast, very little is known about plant NF-Y homologs. HereArabidopsis NF-YA subunits were isolated to determine whether they could form a hete-rotrimeric NF-Y complex with mammalian NF-YB and NF-YC. This resultant chimeric NF-Y complex had DNA binding ability to the same CCAAT sequences as those of the other life systems. Therefore, it is possible that plant NF-Y homologs might have biochemical characteristics similar to mammalian NF-Y, thereby suggesting its functional conservation among organisms.     

Requirement for down-regulation of the CCAAT-binding activity of the NF-Y transcription factor during skeletal muscle differentiation

NF-Y is composed of three subunits, NF-YA, NF-YB, and NF-YC, all required for DNA binding. All subunits are expressed in proliferating skeletal muscle cells, whereas NF-YA alone is undetectable in terminally differentiated cells in vitro. By immunohistochemistry, we show that the NF-YA protein is not expressed in the nuclei of skeletal and cardiac muscle cells in vivo. By chromatin immunoprecipitation experiments, we demonstrate herein that NF-Y does not bind to the CCAAT boxes of target promoters in differentiated muscle cells. Consistent with this, the activity of these promoters is down-regulated in differentiated muscle cells. Finally, forced expression of the NF-YA protein in cells committed to differentiate leads to an impairment in the down-regulation of cyclin A, cyclin B1, and cdk1 expression and is accompanied by a delay in myogenin expression. Thus, our results indicate that the suppression of NF-Y function is of crucial importance for the inhibition of several cell cycle genes and the induction of the early muscle-specific program in postmitotic muscle cells.     

17beta-estradiol (E2) induces cdc25A gene expression in breast cancer cells by genomic and non-genomic pathways

Cdc25A is a potent tyrosine phosphatase that catalyzes specific dephosphorylation of cyclin/cyclin-dependent kinase (cdk) complexes to regulate G1 to S-phase cell cycle progression. Cdc25A mRNA levels are induced by 17beta-estradiol (E2) in ZR-75 breast cancer cells, and deletion analysis of the cdc25A promoter identified the -151 to -12 region as the minimal E2-responsive sequence. Subsequent mutation/deletion analysis showed that at least three different cis-elements were involved in activation of cdc25A by E2, namely, GC-rich Sp1 binding sites, CCAAT motifs that bind NF-Y, and E2F sites that bind DP/E2F1 proteins. Studies with inhibitors and dominant negative expression plasmids show that E2 activates cdc25A expression through activation of genomic ERalpha/Sp1 and E2F1 and cAMP-dependent activation of NF-YA. Thus, both genomic and non-genomic pathways of estrogen action are involved in induction of cdc25A in breast cancer cells.     

The roles of sterol regulatory element-binding proteins in the transactivation of the rat ATP citrate-lyase promoter

ATP citrate-lyase (ACL) is a key enzyme supplying acetyl-CoA for fatty acid and cholesterol synthesis. Its expression is drastically up-regulated when an animal is fed a low fat, high carbohydrate diet after prolonged fasting. In this report, we describe the role of sterol regulatory element-binding proteins (SREBPs) in the transactivation of the rat ACL promoter. ACL promoter activity was markedly stimulated by the overexpression of SREBP-1a and, to a lesser extent, by SREBP-2 in Alexander human hepatoma cells. The promoter elements responsive to SREBPs were located within the 55-base pair sequences from -114 to -60. The gel mobility shift assay revealed four SREBP-1a binding sites in this region. Of these four elements, the -102/-94 region, immediately upstream of the inverted Y-box, and the -70/-61 region, just adjacent to Sp1 binding site, played critical roles in SREBPs-mediated stimulation. The mutation in the inverted Y-box and the coexpression of dominant negative nuclear factor-Y (NF-Y) significantly attenuated the transactivation by SREBP-1a, suggesting that NF-Y binding is a prerequisite for SREBPs to activate the ACL promoter. However, the multiple Sp1 binding sites did not affect the transactivation of the ACL promoter by SREBPs. The binding affinity of SREBP-1a to SREs of the ACL promoter also was much higher than that of SREBP-2. The transactivation potencies of the chimeric SREBPs, of which the activation domains (70 amino acids of the amino terminus) were derived from the different species of their carboxyl-terminal region, were similar to those of SREBPs corresponding to their carboxyl termini. Therefore, it is suggested that the carboxyl-terminal portions of SREBPs containing DNA binding domains are important in determining their transactivation potencies to a certain promoter.     

Asymmetric evolution of duplicate genes encoding the CCAAT-binding factor NF-Y in plant genomes

NF-Y is a ubiquitous CCAAT-binding factor composed of NF-YA, NF-YB and NF-YC. Multiple genes encoding NF-Y subunits have been identified in plant genomes. It remains unclear whether the duplicate genes underwent different evolutionary patterns. Likelihood-ratio tests were used to examine whether the amino acid substitution rates are the same between duplicate genes. The influences of selection on evolution were evaluated by comparing the conservative and radical amino acid substitution rates, as well as maximum-likelihood analysis. Some NF-YB and NF-YC duplicates showed significant evidence of asymmetric evolution but not the NF-YA duplicates. Most amino acid replacements in the NF-YB and NF-YC duplicates result in changes in hydropathy, polar requirement and polarity. The physicochemical changes in the sequences of NF-YB seem to be coupled to asymmetric divergence in gene function. Plant NF-Y genes have evolved in different patterns. Relaxed selective constraints following gene duplication are most likely responsible for the unequal evolutionary rates and distinct divergence patterns of duplicate NF-Y genes. Positive selection may have promoted amino acid hydropathy changes in the NF-YC duplicates.     

Dissection of the NF-Y transcriptional activation potential.

NF-Y is a trimeric CCAAT-binding factor with histone fold subunits (NF-YB/NF-YC) and bipartite activation domains located on NF-YA and NF-YC. We reconstituted the NF-Y activation potential in vivo with GAL4 DBD fusions. In the GAL4-YA configuration, activation requires co-expression of the three subunits; with GAL4-YB and GAL4-YC, transfections of the histone fold partners are sufficient, provided that the Q-rich domain of NF-YC is present. Combinations of mutants indicate that the Q-rich domains of NF-YA and NF-YC are redundant in the trimeric complex. Glutamines 101 and 102 of NF-YA are required for activity. We assayed NF-Y on different promoter targets, containing single or multiple GAL4 sites: whereas on a single site NF-Y is nearly as powerful as VP16, on multiple sites neither synergistic nor additive effects are observed. NF-Y activates TATA and Inr core elements and the overall potency is in the same range as other Q-rich and Pro-rich activation domains. These results represent the first in vivo evidence of subunit interactions studies and further support the hypothesis that NF-Y is a general promoter organizer rather than a brute activator.