Id1 regulation of cellular senescence through transcriptional repression of p16/Ink4a

The Id family of helix–loop–helix (HLH) transcriptional regulatory proteins does not possess a basic DNA-binding domain and functions as a negative regulator of basic HLH transcription factors. Id proteins coordinate cell growth and differentiation pathways within mammalian cells and have been shown to regulate G1-S cell-cycle transitions. Although much recent data has implicated Id1 in playing a critical role in modulating cellular senescence, no direct genetic evidence has been reported to substantiate such work. Here we show that Id1-null primary mouse embryo fibroblasts undergo premature senescence despite normal growth profiles at early passage. These cells possess increased expression of the tumor-suppressor protein p16/Ink4a but not p19/ARF, and have decreased cyclin-dependent kinase (cdk) 2 and cdk4 kinase activity. We also show that Id1 is able to directly inhibit p16/Ink4a but not p19/ARF promoter activity via its HLH domain, and that Id1inhibits transcriptional activation at E-boxes within the p16/Ink4a promoter. Our data provide, to our knowledge, the first genetic evidence for a role for Id1 as an inhibitor of cellular senescence and suggest that Id1 functions to delay cellular senescence through repression of p16/Ink4a. Because epigenetic and genetic abrogation of p16/Ink4a function has been implicated in the evolution of several human malignancies, we propose that transcriptional regulation of p16/Ink4a may also provide a mechanism for the dysregulation of normal cellular growth controls during the evolution of human malignancies.

Adenosine diphosphate sugar pyrophosphatase prevents glycogen biosynthesis in Escherichia coli

An adenosine diphosphate sugar pyrophosphatase (ASPPase, EC 3.6.1.21) has been characterized by using Escherichia coli. This enzyme, whose activities in the cell are inversely correlated with the intracellular glycogen content and the glucose concentration in the culture medium, hydrolyzes ADP-glucose, the precursor molecule of glycogen biosynthesis. ASPPase was purified to apparent homogeneity (over 3,000-fold), and sequence analyses revealed that it is a member of the ubiquitously distributed group of nucleotide pyrophosphatases designated as “nudix” hydrolases. Insertional mutagenesis experiments leading to the inactivation of the ASPPase encoding gene, aspP, produced cells with marginally low enzymatic activities and higher glycogen content than wild-type bacteria. aspP was cloned into an expression vector and introduced into E. coli. Transformed cells were shown to contain a dramatically reduced amount of glycogen, as compared with the untransformed bacteria. No pleiotropic changes in the bacterial growth occurred in both the aspP-overexpressing and aspP-deficient strains. The overall results pinpoint the reaction catalyzed by ASPPase as a potential step of regulating glycogen biosynthesis in E. coli.

The role of haustoria in sugar supply during infection of broad bean by the rust fungus Uromyces fabae

Biotrophic plant pathogenic fungi differentiate specialized infection structures within the living cells of their host plants. These haustoria have been linked to nutrient uptake ever since their discovery. We have for the first time to our knowledge shown that the flow of sugars from the host Vicia faba to the rust fungus Uromyces fabae seems to occur largely through the haustorial complex. One of the most abundantly expressed genes in rust haustoria, the expression of which is negligible in other fungal structures, codes for a hexose transporter. Functional expression of the gene termed HXT1 in Saccharomyces cerevisiae and Xenopus laevis oocytes assigned a substrate specificity for d-glucose and d-fructose and indicated a proton symport mechanism. Abs against HXT1p exclusively labeled haustoria in immunofluorescence microscopy and the haustorial plasma membrane in electron microscopy. These results suggest that the fungus concentrates this transporter in haustoria to take advantage of a specialized compartment of the haustorial complex. The extrahaustorial matrix, delimited by the plasma membranes of both host and parasite, constitutes a newly formed apoplastic compartment with qualities distinct from those of the bulk apoplast. This organization might facilitate the competition of the parasite with natural sink organs of the host.

Histone deacetylase-dependent transcriptional repression by pRB in yeast occurs independently of interaction through the LXCXE binding cleft

We have developed a yeast model system to address transcriptional repression by the retinoblastoma protein (pRB). When fused to the DNA-binding domain of Gal4p (DB-pRB), pRB can repress transcription of reporter genes containing Gal4p binding sites; the histone deacetylase activity encoded by yeast RPD3 is required for DB-pRB repression. Mutation of the LXCXE binding cleft in pRB, a region reported to be required for histone deacetylase recruitment, does not interfere with pRB-mediated repression. From these findings based on yeast experiments, we surmise that the small pocket region of pRB must contain an additional domain that confers histone deacetylase-dependent transcriptional repression. This hypothesis was verified by experiments examining pRB-dependent histone deacetylase association in mammalian cells. In addition to RPD3, repression by pRB in yeast requires MSI1, an ortholog of RbAp48, but not SIN3 or SAP30. By comparing the genetic requirements of DB-pRB repression in yeast to those of other DB-repressor fusions, we can suggest a mechanism by which pRB recruits histone deacetylase activity.

Long-range repression in the Drosophila embryo.

Transcriptional repressors can be characterized by their range of action on promoters and enhancers. Short-range repressors interact over distances of 50-150 bp to inhibit, or quench, either upstream activators or the basal transcription complex. In contrast, long-range repressors act over several kilobases to silence basal promoters. We describe recent progress in characterizing the functional properties of one such long-range element in the Drosophila embryo and discuss the contrasting types of gene regulation that are made possible by short- and long-range repressors.

The physical and genomic organization of microsatellites in sugar beet.

Microsatellites, tandem arrays of short (2-5 bp) nucleotide motifs, are present in high numbers in most eukaryotic genomes. We have characterized the physical distribution of microsatellites on chromosomes of sugar beet (Beta vulgaris L.). Each microsatellite sequence shows a characteristic genomic distribution and motif-dependent dispersion, with site-specific amplification on one to seven pairs of centromeres or intercalary chromosomal regions and weaker, dispersed hybridization along chromosomes. Exclusion of some microsatellites from 18S-5.8S-25S rRNA gene sites, centromeres, and intercalary sites was observed. In-gel and in situ hybridization patterns are correlated, with highly repeated restriction fragments indicating major centromeric sites of microsatellite arrays. The results have implications for genome evolution and the suitability of particular microsatellite markers for genetic mapping and genome analysis.

SMRT isoforms mediate repression and anti-repression of nuclear receptor heterodimers.

Transcriptional repression represents an important component in the regulation of cell differentiation and oncogenesis mediated by nuclear hormone receptors. Hormones act to relieve repression, thus allowing receptors to function as transcriptional activators. The transcriptional corepressor SMRT was identified as a silencing mediator for retinoid and thyroid hormone receptors. SMRT is highly related to another corepressor, N-CoR, suggesting the existence of a new family of receptor-interacting proteins. We demonstrate that SMRT is a ubiquitous nuclear protein that interacts with unliganded receptor heterodimers in mammalian cells. Furthermore, expression of the receptor-interacting domain of SMRT acts as an antirepressor, suggesting the potential importance of splicing variants as modulators of thyroid hormone and retinoic acid signaling.

Concerted repression of an immunoglobulin heavy-chain enhancer, 3' alpha E(hs1,2).

The transcription factor, B-cell-specific activator protein (BSAP), represses the murine immunoglobulin heavy-chain 3' enhancer 3' alpha E(hs1,2) in B cells. Analysis of various 3'alpha E deletional constructs indicates that sequences flanking a and b BSAP-binding sites are essential for appropriate regulation of the enhancer. An octamer motif 5' of the a site and a specific G-rich motif 3' of the b site were identified by competition in electrophoretic mobility-shift assays and methylation-interference foot-printing analysis. Site-directed mutagenesis of either the octamer or G-rich sites resulted in the complete release of repression of 3' alpha E(hs1,2), implicating these two motifs in the repression of this enhancer in B cells. However, when both BSAP-binding sites were mutated, the octamer and G-rich motifs functioned as activators. Moreover, in plasma cells, when BSAP is not expressed, 3' alpha E(hs1,2) is active, and its activity depends on the presence of the other two factors. These results suggest that in B cells, 3' alpha E (hs1,2) is down-regulated by the concerted actions of BSAP, octamer, and G-rich DNA-binding proteins. Supporting this notion of concerted repression, a physical interaction between BSAP and octamer-binding proteins was demonstrated using glutathione S-transferase fusion proteins. Thus, concerted repression of 3' alpha E (hs1,2) in B cells provides a sensitive mechanism by which this enhancer, either individually or as part of a locus-controlling region, is highly responsive to any of several participating factors.

Gene repression by the ferric uptake regulator in Pseudomonas aeruginosa: cycle selection of iron-regulated genes.

The expression of at least 24 distinct genes of Pseudomonas aeruginosa PAO1 is under direct control of the "ferric uptake regulator" (Fur). Novel targets of the Fur protein were isolated in a powerful SELEX (systematic evolution of ligands by exponential enrichment)-like cycle selection consisting of in vitro DNA-Fur interaction, binding to anti-Fur antibody, purification on protein G, and PCR amplification. DNA fragments obtained after at least three exponential enrichment cycles were cloned and subjected to DNA mobility-shift assays and DNase I footprint analyses to verify the specific interaction with the Fur protein in vitro. Iron-dependent expression of the corresponding genes in vivo was monitored by RNase protection analysis. In total, 20 different DNA fragments were identified which represent actual Pseudomonas iron-regulated genes (PIGs). While four PIGs are identical to already known genes (pfeR, pvdS, tonB, and fumC, respectively), 16 PIGs represent previously unknown genes. Homology studies of the putative proteins encoded by the PIGs allowed us to speculate about their possible function. Two PIG products were highly similar to siderophore receptors from various species, and three PIG products were significantly homologous to alternative sigma factors. Furthermore, homologs of the Escherichia coli ORF1-tolQ, nuoA, stringent starvation protein Ssp, and of a two-component regulatory system similar to the Pseudomonas syringae LemA sensor kinase were identified. The putative gene products of seven additional PIGs did not show significant homologies to any known proteins. The PIGs were mapped on the P.aeruginosa chromosome. Their possible role in iron metabolism and virulence of P. aeruginosa is discussed.

Repression of a matrix metalloprotease gene by E1A correlates with its ability to bind to cell type-specific transcription factor AP-2.

Adenovirus E1A 243-amino acid protein can repress a variety of enhancer -linked viral and cellular promoters. This repression is presumed to be mediated by its interaction with and sequestration of p3OO, a transcriptional coactivator. Type IV 72-kDa collagenase is one of the matrix metalloproteases that has been implicated in differentiation, development, angiogenesis, and tumor metastasis. We show here that the cell type-specific transcription factor AP-2 is an important transcription factor for the activation of the type IV 72-kDa collagenase promoter and that adenovirus E1A 243-amino acid protein represses this promoter by targeting AP-2. Glutathione S-transferase-affinity chromatography studies show that the E1A protein interacts with the DNA binding/dimerization region of AP-2 and that the N-terminal amino acids of E1A protein are required for this interaction. Further, E1A deletion mutants which do not bind to p3OO can repress this collagenase promoter as efficiently as the wildtype E1A protein. Because the AP-2 element is present in a variety of viral and cellular enhancers which are repressed by E1A, these studies suggest that E1A protein can repress cellular and viral promoter/enhancers by forming a complex with cellular transcription factors and that this repression mechanism may be independent of its interaction with p3OO.

A role for the Msx-1 homeodomain in transcriptional regulation: residues in the N-terminal arm mediate TATA binding protein interaction and transcriptional repression.

In a previous study we showed that the murine homeodomain protein Msx-1 is a potent transcriptional repressor and that this activity is independent of its DNA binding function. The implication of these findings is that repression by Msx-1 is mediated through its association with certain protein factors rather than through its interaction with DNA recognition sites, which prompted investigation of the relevant protein factors. Here we show that Msx-1 interacts directly with the TATA binding protein (TBP) but not with several other general transcription factors. This interaction is mediated by the Msx-1 homeodomain, specifically through residues in the N-terminal arm. These same N-terminal arm residues are required for repression by Msx-1, suggesting a functional relationship between TBP association and transcriptional repression. This is further supported by the observation that addition of excess TBP blocks the repressor action of Msx-1 in in vitro transcription assays. Finally, DNA binding activity is separable from both TBP interaction and repression, which further shows that these other activities of the Msx-1 homeodomain are distinct. Therefore, these findings define a role for the Msx-1 homeodomain, particularly the N-terminal arm residues in protein-protein interaction and transcriptional repression, and implicate a more complex role overall for homeodomains in transcriptional regulation.

Krüppel-associated box-mediated repression of RNA polymerase II promoters is influenced by the arrangement of basal promoter elements.

The evolutionarily conserved Krüppel-associated box (KRAB) is present in the N-terminal regions of more than one-third of all Krüppel-class zinc finger proteins. Recent experiments have demonstrated that the KRAB-A domain tethered to a promoter DNA by connecting to heterologous DNA-binding protein domain or targeted to a promoter-proximal RNA sequence acts as a transcriptional silencing of RNA polymerase II promoters. Here we show that expression of KRAB domain suppresses in vivo the activating function of various defined activating transcription factors, and we demonstrate that the KRAB domain specifically silences the activity of promoters whose initiation is dependent on the presence of a TATA box. Promoters whose accurate transcription initiation is directed by a pyrimidine-rich initiator element, however, are relatively unaffected. We also report in vitro transcription experiments indicating that the KRAB domain is able to repress both activated and basal promoter activity. Thus, the KRAB domain appears to repress the activity of certain promoters through direct communication with TATA box-dependent basal transcription machinery.

Importance of the carboxyl-terminal domain of enzyme I of the Escherichia coli phosphoenolpyruvate: sugar phosphotransferase system for phosphoryl donor specificity.

The first protein component of the Escherichia coli phosphoenolpyruvate: sugar phosphotransferase system (PTS) is the 64-kDa protein enzyme I (EI), which can be phosphorylated by phosphoenolpyruvate (PEP) and carry out phosphotransfer to the acceptor heat-stable protein (HPr). The isolated amino-terminal domain (EIN) of E. coli EI is no longer phosphorylated by PEP but retains the ability to participate in reversible phosphotransfer to HPr. An expression vector was constructed for the production of large amounts of EIN, and conditions were developed for maximal expression of the protein. A three-column procedure is described for purification to homogeneity of EIN; a 500-ml culture yields approximately 80 mg of pure protein in about a 75% yield. Intact E. coli EI is effective in phosphotransfer from PEP to HPr from E. coli but not to the HPrs from Bacillus subtilis or Mycoplasma capricolum. Phosphotransfer from EI to enzyme IIAglc (EIIAglc) from E. coli or M. capricolum requires the intermediacy of HPr. The phosphorylated form of EIN is capable of more general phosphotransfer; it will effect phosphotransfer to HPrs from E. coli, B. subtilis, and M. capricolum as well as to EIAglc from E. coli. These studies demonstrate that the carboxyl-terminal domain of EI confers on the protein the capability to accept a phosphoryl group from PEP as well as a discriminator function that allows the intact protein to promote effective phosphoryl transfer only to E. coli HPr.

Selective repression of transcriptional activators by Pbx1 does not require the homeodomain.

PBX1 is a homeobox-containing gene identified as the chromosome 1 participant of the t(1;19) chromosomal translocation of childhood pre-B-cell acute lymphoblastic leukemia. This translocation produces a fusion gene encoding the chimeric oncoprotein E2A-Pbx1, which can induce both acute myeloid and T-lymphoid leukemia in mice. The binding of Pbx1 to DNA is weak; however, both Pbx1 and E2A-Pbx1 exhibit tight binding to specific DNA motifs in conjunction with certain other homeodomain proteins, and E2A-Pbx1 activates transcription through these motifs, whereas Pbx1 does not. In this report, we investigate potential transcriptional functions of Pbx1, using transient expression assays. While no segments of Pbx1 activated transcription, an internal domain of Pbx1 repressed transcription induced by the activation domain of Sp1, but not by the activation domains of VP16 or p53. This Pbx1 domain, which lies upstream of the homeodomain and is highly conserved among Pbx proteins, is thus predicted to bind a specific transcription factor. Surprisingly, the repression activity of Pbx1 did not require homeodomain-dependent DNA binding. Thus, Pbx1 may be able to alter gene transcription by both DNA-binding-dependent and DNA-binding-independent mechanisms.

Transcription factor TFIID is a direct functional target of the adenovirus E1A transcription-repression domain.

The 243-amino acid adenovirus E1A oncoprotein both positively and negatively modulates the expression of cellular genes involved in the regulation of cell growth. The E1A transcription repression function appears to be linked with its ability to induce cellular DNA synthesis, cell proliferation, and cell transformation, as well as to inhibit cell differentiation. The mechanism by which E1A represses the transcription of various promoters has proven enigmatic. Here we provide several lines of evidence that the "TATA-box" binding protein (TBP) component of transcription factor TFIID is a cellular target of the E1A repression function encoded within the E1A N-terminal 80 amino acids. (i) The E1A N-terminal 80 amino acids [E1A-(1-80)protein] efficiently represses basal transcription from TATA-containing core promoters in vitro. (ii) TBP reverses completely E1A repression in vitro. (iii) TBP restores transcriptional activity to E1A-(1-80) protein affinity-depleted nuclear extracts. (iv) The N-terminal repression domain of E1A interacts directly and specifically with TBP in vitro. These results may help explain how E1A represses a set of genes that lack common upstream promoter elements.