👤 Christopher W Rowley

Hepatic nuclear factor (HNF)-4alpha and HNF-1alpha are key endodermal transcriptional regulators that physically and functionally interact. HNF-4alpha and HNF-1alpha cooperatively activate genes with binding sites for both factors, whereas suppressive interactions occur at regulatory sequences with a binding site for only one factor. The liver fatty acid binding protein gene (Fabp1) has binding sites for both factors, and chromatin precipitation assays were utilized to demonstrate that HNF-4alpha increased HNF-1alpha Fabp1 promoter occupancy during cooperative transcriptional activation. The HNF4 P2 promoter contains a HNF-1 but not HNF-4 binding site, and HNF-4alpha suppressed HNF-1alpha HNF4 P2 activation and decreased promoter HNF-1alpha occupancy. The apolipoprotein C III (APOC3) promoter contains a HNF-4 but not HNF-1 binding site, and HNF-1alpha suppressed HNF-4alpha APOC3 activation and decreased HNF-4alpha promoter occupancy. Maturity onset diabetes of the young (MODY) as well as defects in hepatic lipid metabolism result from mutations in either HNF-4alpha or HNF-1alpha. We found that MODY missense mutant R127W HNF-4alpha retained wild-type individual Fabp1 activation and bound to HNF-1alpha better than wild-type HNF-4alpha, yet did not cooperate with HNF-1alpha or increase HNF-1alpha Fabp1 promoter occupancy. The R127W mutant was also defective in both suppressing HNF-1alpha activation of HNF4 P2 and decreasing HNF-1alpha promoter occupancy. The HNF-1alpha R131Q MODY mutant also retained wild-type Fabp1 activation and bound to HNF-4alpha as well as the wild type but was defective in both suppressing HNF-4alpha APOC3 activation and decreasing HNF-4alpha promoter occupancy. These results suggest HNF-1alpha-HNF-4alpha functional interactions are accomplished by regulating factor promoter occupancy and that defective factor-factor interactions may contribute to the MODY phenotype. Show less

Invins(10;11)(p12;q23q12) is one of the rare but recurring chromosome rearrangements seen in acute monoblastic leukemia. We cloned the proximal 10p breakpoint from one patient and showed that the MLL gene at 11q23 was fused to the 3' portion of AF10 at 10p12. In addition, we cloned the telomeric 10p junction and we found that the 5' portion of AF10 was juxtaposed to a previously unidentified gene at 11q12, which we call HEAB (a human homolog to a hypothetical Caenorhabditis elegans ATP/GTP-binding protein). These results indicate that the AF10 gene is split into a 5' AF10 and a 3' AF10 portion by the 11q23q12 chromosome segment and that both breakpoint junctions result in fusion transcripts of 5' AF10/HEAB and MLL/3' AF10. Only the MLL/3' AF10 fusion mRNA results in an in-frame fusion. Northern blot analysis of HEAB expression shows that a 2.0-kb major transcript is expressed ubiquitously in human tissues and is especially abundant in testis and skeletal muscle, whereas a 3.2-kb minor transcript is noted with the highest level of expression in thymus and peripheral blood leukocytes. The HEAB gene encodes a 425-amino acid protein that is rich in valine and leucine. HEAB protein shows high homology in its entire amino acid sequence to a putative C elegans protein and contains an adenosine triphosphate (ATP)/guanosine triphosphate (GTP)-binding motif that has homology to the ATP-binding transporter superfamily or to GTP-binding proteins. Our results could explain the high frequency of complex insertion and other rearrangement events that involve 10p12 and 11q12 and 11q23. The finding that different portions of a single gene are involved in fusions with two independent genes in the same leukemic cell is unique in the analysis of chromosome translocations. Show less

The translocation t(10;11)(p13;q14) is a recurring chromosomal abnormality that has been observed in patients with acute lymphoblastic leukemia as well as acute myeloid leukemia. We have recently reported that the monocytic cell line U937 has a t(10;11)(p13;q14) translocation. Using a combination of positional cloning and candidate gene approach, we cloned the breakpoint and were able to show that AF10 is fused to a novel gene that we named CALM (Clathrin Assembly Lymphoid Myeloid leukemia gene) located at 11q14. AF10, a putative transcription factor, had recently been cloned as one of the fusion partners of MLL. CALM has a very high homology in its N-terminal third to the murine ap-3 gene which is one of the clathrin assembly proteins. The N-terminal region of ap-3 has been shown to bind to clathrin and to have a high-affinity binding site for phosphoinositols. The identification of the CALM/AF10 fusion gene in the widely used U937 cell line will contribute to our understanding of the malignant phenotype of this line. Show less

For cells of the yeast Saccharomyces cerevisiae, heat shock causes a transient inhibition of the cell cycle-regulatory step START. We have determined that this heat-induced START inhibition is accompanied by decreased CLN1 and CLN2 transcript abundance and by possible posttranscriptional changes to CLN3 (WHI1/DAF1) cyclin activity. Persistent CLN2 expression from a heterologous promoter or the CLN2-1 or CLN3-1 alleles that are thought to encode cyclin proteins with increased stability eliminated heat-induced START inhibition but did not affect other aspects of the heat shock response. Heat-induced START inhibition was shown to be independent of functions that regulate cyclin activity under other conditions and of transcriptional regulation of SWI4, an activator of cyclin transcription. Cells lacking Bcy1 function and thus without cyclic AMP control of A kinase activity were inhibited for START by heat shock as long as A kinase activity was attenuated by mutation. We suggest that heat shock mediates START blockage through effects on the G1 cyclins. Show less

The cell cycle of the budding yeast Saccharomyces cerevisiae has been investigated through the study of conditional cdc mutations that specifically affect cell cycle performance. Cells bearing the cdc68-1 mutation (J. A. Prendergast, L. E. Murray, A. Rowley, D. R. Carruthers, R. A. Singer, and G. C. Johnston, Genetics 124:81-90, 1990) are temperature sensitive for the performance of the G1 regulatory event, START. Here we describe the CDC68 gene and present evidence that the CDC68 gene product functions in transcription. CDC68 encodes a 1,035-amino-acid protein with a highly acidic and serine-rich carboxyl terminus. The abundance of transcripts from several unrelated genes is decreased in cdc68-1 mutant cells after transfer to the restrictive temperature, while at least one transcript, from the HSP82 gene, persists in an aberrant fashion. Thus, the cdc68-1 mutation has both positive and negative effects on gene expression. Our findings complement those of Malone et al. (E. A. Malone, C. D. Clark, A. Chiang, and F. Winston, Mol. Cell. Biol. 11:5710-5717, 1991), who have independently identified the CDC68 gene (as SPT16) as a transcriptional suppressor of delta-insertion mutations. Among transcripts that rapidly become depleted in cdc68-1 mutant cells are those of the G1 cyclin genes CLN1, CLN2, and CLN3/WHI1/DAF1, whose activity has been previously shown to be required for the performance of START. The decreased abundance of cyclin transcripts in cdc68-1 mutant cells, coupled with the suppression of cdc68-1-mediated START arrest by the CLN2-1 hyperactive allele of CLN2, shows that the CDC68 gene affects START through cyclin gene expression. Show less