The polymyositis-scleroderma autoantigen interacts with the helix-loop-helix proteins E12 and E47.

The basic helix-loop-helix (bHLH) transcription factors E12 and E47 regulate cellular differentiation and proliferation in diverse cell types. While looking for proteins that bind to E12 and E47 by the yeast interaction trap, we isolated the rat (r) homologue of the human (h) polymyositis-scleroderma autoantigen (PM-Scl), which has been localized to the granular layer of the nucleolus and to distinct nucleocytoplasmic foci. The rPM-Scl and hPM-Scl homologues are 96% similar and 91% identical. We found that rPM-Scl mRNA expression was regulated by growth factor stimulation in cultured rat aortic smooth muscle cells. rPM-Scl bound to E12 and E47 but not to Id3, Gax, Myb, OCT-1, or Max. The C terminus of rPM-Scl (amino acids 283-353) interacted specifically with a 54-amino acid domain in E12 that is distinct from the bHLH domain. Finally, cotransfection of rPM-Scl and E47 specifically increased the promoter activity of a luciferase reporter construct containing an E box and did not affect the basal activity of the reporter construct. rPM-Scl appears to be a novel non-HLH-interacting partner of E12/E47 that regulates E2A protein transcription.

Degradation of E2A proteins through a ubiquitin-conjugating enzyme, UbcE2A.

The helix-loop-helix E2A proteins (E12 and E47) govern cellular growth and differentiation. To identify binding partners that regulate the function of these ubiquitous transcription factors, we screened for proteins that interacted with the C terminus of E12 by the yeast interaction trap. UbcE2A, a rat enzyme that is highly homologous to and functionally complements the yeast ubiquitin-conjugating enzyme UBC9, was identified and cloned. UbcE2A appears to be an E2A-selective ubiquitin-conjugating enzyme because it interacts specifically with a 54-amino acid region in E47-(477-530) distinct from the helix-loop-helix domain. In contrast, most of the UbcE2A protein is required for interaction with an E2A protein. The E2A proteins appear to be degraded by the ubiquitin-proteasome pathway because the E12 half-life of 60 min is extended by the proteasome inhibitor MG132, and E12 is multi-ubiquitinated in vivo. Finally, antisense UbcE2A reduces E12 degradation. By participating in the degradation of the E2A proteins, UbcE2A may regulate cell growth and differentiation.

Effect of decreased fte-1 gene expression on protein synthesis, cell growth, and transformation.

The fte-1 gene, previously cloned in our laboratory as a putative v-fos transformation effector gene (C.J. Kho and H. Zarbl, Proc. Natl. Acad. Sci. USA, 89: 2200-2204, 1992), has been shown to encode ribosomal protein S3a. Comparison of fte-1 expression in a variety of normal and transformed cells indicated that elevated expression of fte-1 mRNA was frequently associated with transformation of rodent and human cells. In an effort to understand how monoallelic disruption of fte-1 is able to block v-fos-induced cell transformation, we examined the pattern of fte-1 expression during cell cycle progression and determined its effects on protein synthesis and cell growth. In synchronously cultured human fibroblasts, fte-1 mRNA was found to accumulate in cells undergoing DNA synthesis, suggesting that its expression is correlated with S-phase progression. fte-1 does not function as a dominant oncogene because ectopic overexpression of fte-1 in normal Rat-1 fibroblasts failed to induce cell transformation. However, the expression of antisense fte-1 resulted in growth inhibition. Monoallelic disruption of the fte-1 gene in v-fos-transformed Rat-1 fibroblasts resulted not only in loss of the transformed phenotype but also in a decreased rate of protein synthesis due to decreased polysome formation. Taken together, these results indicate that the accumulation of ribosomal subunits and the rate of protein synthesis are important modulators of neoplastic transformation and cell growth.

APEG-1, a novel gene preferentially expressed in aortic smooth muscle cells, is down-regulated by vascular injury.

Despite the importance of phenotypic alterations in arterial smooth muscle cells (ASMC) during the pathogenesis of arteriosclerosis, little is known about genes that define differentiated ASMC. Using differential mRNA display, we isolated a novel gene preferentially expressed in the rat aorta and termed this gene APEG-1. The cDNA of rat APEG-1 contained an open reading frame encoding 113 amino acids, which would predict a basic protein of 12.7 kDa. The amino acid sequence of rat APEG-1 was highly conserved among human and mouse homologues (97 and 98%, respectively). Using an APEG-1 fusion protein containing an N-terminal c-Myc tag, we identified APEG-1 as a nuclear protein. By in situ hybridization, APEG-1 mRNA was expressed in rat ASMC. Although APEG-1 was expressed highly in differentiated ASMC in vivo, its expression was quickly down-regulated and disappeared in dedifferentiated ASMC in culture. In vivo, APEG-1 mRNA levels decreased by more than 80% in response to vascular injury as ASMC changed from a quiescent to a proliferative phenotype. Taken together, these data indicate that APEG-1 is a novel marker for differentiated ASMC and may have a role in regulating growth and differentiation of this cell type.

Fte-1, a v-fos transformation effector gene, encodes the mammalian homologue of a yeast gene involved in protein import into mitochondria.

Revertants were isolated from v-fos-transformed rat-1 cells cotransfected with a human cDNA expression library and a selectable marker (pMEX-neo). Molecular analysis of one clone, R2.2, suggested that the revertant phenotype resulted from the disruption of a transformation effector gene by the integration of the pMEX-neo plasmid. Genomic sequences flanking the plasmid integration site were cloned and used as probes in Northern blot analyses. A probe derived from sequences 5' to the integration site hybridized to a unique 1.2-kilobase mRNA and was used to isolate a 0.9-kilobase cDNA clone (fte-1). The open reading frame of the fte-1 cDNA predicts a highly basic protein that shows a remarkable level of similarity with two genes from Saccharomyces cerevisiae. One of these yeast genes contains an unidentified open reading frame and the other, MFT1, is a gene isolated from a yeast mutant that fails to import a fusion protein into mitochondria [Garrett, J. M., Singh, K. K., Vonder Haar, R. A. & Emr, S. D. (1991) Mol. Gen. Genet. 225, 483-491]. Expression of the fte-1 gene was induced approximately 5-fold in v-fos-transformed fibroblasts, but expression was reduced in clone R2.2 and in several independent revertant clones. Transfection of R2.2 cells with fte-1 expression vectors resulted in the reacquisition of a transformed phenotype. These results demonstrate that the mammalian homologue of a gene implicated in protein import into yeast mitochondria is a v-fos transformation effector gene.

Functional in vitro assays for the isolation of cell transformation effector and suppressor genes.

Malignant transformation may be viewed as an imbalance between signals inducing cell growth and signals leading to growth inhibition, differentiation, or senescence. A basic understanding of how these counterbalancing forces interact to regulate normal cell growth is the prerequisite to comprehending the mechanisms of tumorigenesis. Identification and characterization of the gene products implicated in these regulatory pathways is the first step toward understanding the disease process. The studies outlined here provide the potential basis for isolating and molecularly characterizing transformation effector and suppressor genes, which must respectively function in the positive and negative regulation of normal cell growth. The general strategy used involves the isolation and molecular characterization of nontransformed variants (revertants) from populations of tumor cells. The selection of revertants is facilitated by the ability to separate normal from transformed cells by fluorescence-activated sorting. The basis for this separation is the differential retention of the fluorescent dye rhodamine 123 in the mitochondria of normal versus transformed cells. Using this approach, we have isolated revertants from a mutagenized population of v-fos-transformed Rat-1 fibroblasts. Characterization of these clones indicated that they had sustained causal mutations in transformation effector genes. The unmutated effector genes are being identified and molecularly cloned by isolating retransformed clones from revertant cell lines that have been transfected with DNA or cDNA from normal primary cells. The same selection protocol has also been used to isolate revertants from tumor cell lines that have been transfected with DNA or cDNA from primary cells. The putative tumor-suppressor genes present in these revertants are currently being analyzed.

Identification and isolation of methionine-cysteine rich proteins in soybean seed.

We recently developed a method to identify methionine-containing proteins and quantitate their methionine contents. We applied this method to soybeans and identified relatively methionine-rich proteins (MRP) among the albumins. By acidic methanol extraction of the albumins, we obtained a group of low molecular weight methionine-cysteine rich proteins (MCRP) that analyzed 4.0% methionine and 8.8% cysteine. MCRP made up 1-2% of the total protein in soybeans. Reversed-phase HPLC purification of MCRP yielded a protein peak that exhibited a single major band on denaturing polyacrylamide gel electrophoresis, had a molecular weight of 16 kD and contained 6.2% methionine and 18.8% cysteine. We are cloning the gene for this protein. Increasing its level through genetic engineering could increase the methionine-cysteine content of soybeans.