A Stat3-interacting protein (StIP1) regulates cytokine signal transduction.

Genetic and biochemical studies have led to the identification of the Stat3-Interacting Protein StIP1. The preferential association of StIP1 with inactive (i.e., unphosphorylated) Stat3 suggests that it may contribute to the regulation of Stat3 activation. Consistent with this possibility, StIP1 also exhibits an affinity for members of the Janus kinase family. Overexpression of the Stat3-binding domain of StIP1 blocks Stat3 activation, nuclear translocation, and Stat3-dependent induction of a reporter gene. These studies indicate that StIP1 regulates the ligand-dependent activation of Stat3, potentially by serving as a scaffold protein that promotes the interaction between Janus kinases and their Stat3 substrate. The ability of StIP1 to associate with several additional members of the signal transducer and activator of transcription family suggests that StIP1 may serve a broader role in cytokine-signaling events.

Functional STAT 1 and 3 signaling by the leptin receptor (OB-R); reduced expression of the rat fatty leptin receptor in transfected cells.

The leptin receptor (OB-R) bears homology to members of the class I cytokine receptor family. We demonstrate that leptin binding to OB-R stimulates formation of STAT-1 and STAT-3 complexes, thereby defining transcriptional motifs for genes that are under leptin control. Transfected fa OB-R bound leptin with equal affinity to that of wild type OB-R. fa OB-R abundance was about 7 fold reduced compared to control cells. Surprisingly, the low level of fa OB-R is fully capable of activating the STAT signal transduction pathway. We discuss plausible explanations for the obese phenotype in Zucker fatty rats.

DNA binding by N- and L-Myc proteins.

N- and L-Myc, like c-Myc, contain adjacent basic region (BR), helix-loop-helix (HLH) and leucine zipper (LZ) motifs, which characterize a family of DNA-binding proteins. We have used a polymerase chain reaction (PCR)-based binding site selection technique to demonstrate that the most highly preferred binding site for both N- and L-Myc fusion proteins contains a CACGTG motif, the core binding sequence previously identified for c-Myc. Further analysis identified other N-Myc binding sequences, including asymmetric sequences such as CAT-GTG. N-Myc, like c-Myc, preferentially forms heterodimeric DNA-binding complexes with Max protein. Mutational analyses of N-Myc basic region (BR), helix-loop-helix (HLH) and leucine zipper (LZ) regions revealed that all three regions are necessary for DNA binding by N-Myc-Max complexes, and that dimerization requires both HLH and LZ motifs, while BR sequences are needed only for DNA binding. Our findings support the notion that the LZ motif is a critical element in dimer formation by bHLH-LZ proteins.

A novel POU homeodomain gene specifically expressed in cells of the developing mammalian nervous system.

We report the isolation of a novel human POU domain encoding gene named RDC-1. The POU domain of the RDC-1 encoded protein is highly related to the POU domain potentially encoded by the rat brain-3 sequence and to that of the Drosophila I-POU protein; outside of the POU region, RDC-1 is unrelated to any previously characterized protein. The RDC-1 gene is expressed almost exclusively in normal tissues and transformed cells of neural origin. In the developing mouse and human fetus, RDC-1 is expressed in a spatially and temporally restricted pattern that suggests a critical role in the differentiation of neuronal tissues. In addition, RDC-1 is expressed in a unique subset of tumors of the peripheral nervous system including neuroepitheliomas and Ewing's sarcomas but not neuroblastomas. Based on its unique structural characteristics and expression pattern, we discuss potential functions for the RDC-1 protein.

Structure and expression of canary myc family genes.

We found that the canary N-myc gene is highly related to mammalian N-myc genes in both the protein-coding region and the long 3' untranslated region. Examined coding regions of the canary c-myc gene were also highly related to their mammalian counterparts, but in contrast to N-myc, the canary and mammalian c-myc genes were quite divergent in their 3' untranslated regions. We readily detected N-myc and c-myc expression in the adult canary brain and found N-myc expression both at sites of proliferating neuronal precursors and in mature neurons.

Are myc proteins transcription factors?

Expression of the myc family of cellular proto-oncogenes is critical for determining the proliferative, differentiative, and oncogenic potential of a wide variety of cell types. Despite a large body of genetic and biochemical data indicating that myc proteins are located in the nucleus and can bind to nucleic acids, the mechanism by which these proteins exert their effects remains a mystery. The recent observation that myc proteins contain two structural domains previously identified in transcription factors and differentiation factors, the leucine zipper domain and the helix-loop-helix motif, supports the notion that these proteins directly regulate gene expression. In this review we consider the possible significance of these domains to myc function.

Structure and expression of the murine L-myc gene.

We have isolated a 12 kb clone from the murine genome which we show by DNA transfection studies to contain an entire functional L-myc gene and the transcriptional promoter sequences necessary for its expression. We have also isolated a 3.1 kb cDNA sequence from a murine brain cDNA library which corresponds to most of the L-myc mRNA. We have identified the L-myc coding region within the genomic clone by a combination of S1 nuclease analyses. Northern blotting analyses and comparative nucleotide sequence analyses with the cDNA clone. The L-myc gene appears to be organized similarly to the other well-characterized myc-family genes, c-myc and N-myc. The predicted amino acid coding sequence of the L-myc gene indicates that the L-myc protein is significantly smaller than c- and N-myc, but is highly related. In particular, comparison of the N- and c-myc protein sequences reveals seven relatively conserved regions interspersed among non-conserved regions; the L-myc gene retains five of these conserved regions but lacks two others. In addition, a portion of one highly conserved region is encoded within a different region of the L-myc gene but, due to changes in the size of L-myc exons relative to those of N- and c-myc, maintains its overall position in the peptide backbone with respect to other conserved regions. We discuss these findings in the context of potential functional domains and the possibility of overlapping and distinct activities of myc-family proteins.

Myc family of cellular oncogenes.

The myc family of cellular oncogenes contains three well-defined members: c-myc, N-myc and L-myc. Additional structural and functional evidence now suggests that other myc-family oncogenes exist. The overall structure and organization of the c-, N-, and L-myc genes and transcripts are very similar. Each gene contains three exons: encoding a long 5' untranslated leader and a long 3' untranslated region. The proteins encoded by these myc genes share several stretches of significant homology. The conservation of sequences at the carboxyterminus of the L-myc protein suggests that it is also a DNA-binding, nuclear-associated protein. Each myc gene will cooperate with an activated Ha-ras oncogene to cause transformation of primary rat embryo fibroblasts. Characteristics of several new myc-family members are described.

Differential expression of myc family genes during murine development.

The myc family of cellular oncogenes contains three known members. The N-myc and c-myc genes have 5'-noncoding exons, strikingly homologous coding regions, and display similar oncogenic potential in an in vitro transformation assay. The L-myc gene is less well characterized, but shows homology to N-myc and c-myc (ref. 6; also see below). c-myc is expressed in most dividing cells, and deregulated expression of this gene has been implicated in the development of many classes of tumours. In contrast, expression of N-myc has been found only in a restricted set of tumours, most of which show neural characteristics; these include human neuroblastoma, retinoblastoma and small cell lung carcinoma (SCLC). L-myc expression has so far been found only in SCLC. Activated N-myc and L-myc expression has been implicated in oncogenesis; for example, although N-myc expression has been found in all neuroblastomas tested, activated (greatly increased) N-myc expression, resulting from gene amplification, is correlated with progression of the tumour. We now report that high-level expression of N- and L-myc is very restricted with respect to tissue and stage in the developing mouse, while that of c-myc is more generalized. Furthermore, we demonstrate that N-myc is not simply a neuroectoderm-specific gene; both N- and L-myc seem to be involved in the early stages of multiple differentiation pathways. Our findings suggest that differential myc gene expression has a role in mammalian development and that the normal expression patterns of these genes generally predict the types of tumours in which they are expressed or activated.