Ada Houweling

The PHD Type Zinc Finger Is an Integral Part of the CBP Acetyltransferase Domain

ABSTRACT Histone acetyltransferases (HATs) such as CBP and p300 are regarded as key regulators of RNA polymerase II-mediated transcription, but the critical structural features of their HAT modules remain ill defined. The HAT domains of CBP and p300 are characterized by the presence of a highly conserved putative plant homeodomain (PHD) (C4HC3) type zinc finger, which is part of the functionally uncharacterized cysteine-histidine-rich region 2 (CH2). Here we show that this region conforms to the PHD type zinc finger consensus and that it is essential for in vitro acetylation of core histones and the basal transcription factor TFIIE34 as well as for CBP autoacetylation. PHD finger mutations also reduced the transcriptional activity of the full-length CBP protein when tested on transfected reporter genes. Importantly, similar results were obtained on integrated reporters, which reflect a more natural chromatinized state. Taken together, our results indicate that the PHD finger forms an integral part of the enzymatic core of the HAT domain of CBP.

Characterization of cells transformed by Ad5/Ad12 hybrid early region I plasmids

Early region I (EI) of the human adenoviruses consists of two transcriptional units, EIa and EIb. We have constructed plasmids containing hybrid EI regions from the nononcogenic adenovirus type 5 (Ad5) and the highly oncogenic Ad12. Each plasmid essentially contains the EIa region of one serotype and the EIb region of the other serotype. These hybrid EI plasmids are capable of transforming baby rat kidney cells into cell lines with the typical adenovirus-transformed phenotype, indicating an extensive functional homology between the EI transcriptional units of the two serotypes at the level of transformation. The difference in transformation frequency between the two hybrid EI plasmids suggests that the efficiency of transformation is determined by the identity of the EIa region, i.e., the efficiency is high for clones containing the EIa region of Ad5 and low for clones containing the EIa region of Ad12. In nude mice the Ad5 EIa-Ad12 EIb hybrid-transformed cells show the same high oncogenic potential as Ad12 EI-transformed cells, whereas the Ad12 EIa-Ad5 EIb hybrid-transformed cells express an even lower potential than the Ad5 El-transformed cells, indicating that the difference in oncogenic potential between Ad5- and Ad12-transformed cells is specified by the EIb region.

The relationship between region E1a and E1b of human adenoviruses in cell transformation.

Baby rat kidney (BRK) cells were transfected either with intact region E1 DNA of adenovirus type 5 (Ad5) or with mixtures of DNA fragments containing the separated E1a and E1b regions. The results showed that mixtures of regions E1a and E1b transform with a similar efficiency as intact region E1. DNA fragments containing region E1b alone have no detectable transforming activity in primary BRK cells nor in established rat cell lines. When region E1a and Ad5 was combined with region E1b and Ad12 complete transformation was also obtained. Characterization of the cell lines transformed by separated E1a and E1b regions have led to the following conclusions: (1) Expression of region E1b is not dependent on specific linkage to region E1a as it occurs in the intact E1 region. (2) Region E1b is normally expressed into the corresponding major adenovirus T antigens (65,000 and 19,000 Mr with region E1b of Ad5; 60,000 and 19,000 Mr with E1b or AD12). (3) Region E1b of Ad12 can be activated by region E1a of Ad5 indicating that the Ela regions of both serotypes are functionally similar in transformation. (4) Cell lines containing region E1b of Ad5 are weakly oncogenic in nude mice whereas cells containing E1b of Ad12 are highly oncogenic in nude mice, indicating that the degree of oncogenicity is determined by region E1b.

Role of the adenovirus early region 1B tumor antigens in transformation and lytic infection

We have investigated the contribution of each of the two adenovirus type 5 (Ad5) major early region 1b (E1b) proteins in cell transformation and in lytic infection. An Ad5 E1 plasmid, in which the reading frame for the 19-kDa E1b protein was abolished by a stop codon close to the initiation codon, transformed primary baby rat kidney (BRK) cells with an efficiency of about half of that of a wild type Ad5 E1 plasmid, whereas a plasmid with a mutation in the gene for the 58-kDa E1b protein transformed the same primary cells with only one-third of the wild type efficiency. Plasmids containing region E1a only or a plasmid carrying mutations in the genes for major E1b proteins all transformed primary cells with an efficiency of approximately 5% of wild type. To test the effect of the E1b mutations in virion-mediated cell transformation, the mutant E1b regions were introduced into intact viral genomes by overlap recombination and were subsequently used in a transformation assay on BRK cells. The 19 and 58-kDa mutant viruses were found to transform BRK cells with 11 and 25% of the efficiency of wild type virus, respectively. These results suggest that the 19-kDa E1b protein is essential for virus-mediated cell transformation, in agreement with results of others, but not for plasmid-mediated cell transformation. In lytic infection, the 19-kDa mutant virus was some 30-fold reduced in yield on HeLa cells, whereas the 58-kDa mutant virus was 3000-fold reduced in its ability to grow on HeLa cells at low multiplicity of infection, but showed a marked multiplicity-dependent leakiness. The 58-kDa mutant virus was not defective when its growth was assayed on human embryonic kidney (HEK) cells. This may indicate that cellular proteins are expressed in HEK cells that are functionally homologous to the 58-kDa E1b protein.

Abnormal kinetics of induction of UV-stimulated recombination in human DNA repair disorders.

Recombination can result in genetic instability, and thus constitutes an important factor in the carcinogenic conversion of mammalian cells. Here we describe the occurrence of UV-stimulated recombination called enhanced recombination (EREC), measured with the use of Herpes Simplex Viruses type 1 mutants. In normal diploid human cells, EREC is induced by UV-C, mitomycin C and ENU, but not by X-ray or MMS. The kinetics of induction of EREC is similar to that of other SOS-like responses such as enhanced reactivation (ER) and enhanced mutagenesis (EM). In contrast to the latter responses, EREC is induced to higher levels and persists for longer periods in DNA repair deficient fibroblasts derived from xeroderma pigmentosum (XP), Cockayne syndrome (CS) and Trichothiodystrophy (TTD) patients. This observation indicates that EREC is a distinct SOS-like response. Apparently, the presence of unrepaired DNA lesions in the host genome is a strongly inducing signal for EREC. On the other hand, in cells derived from patients suffering from Bloom, Werner or Rothmund-Thomson syndrome (RTS) the EREC response is absent. These data indicate that determining EREC is a useful assay to investigate diploid human fibroblasts for abnormalities in UV-stimulated recombination.