Structure and regulation of the envoplakin gene

Envoplakin, a member of the plakin family of proteins, is a component of desmosomes and the epidermal cornified envelope. To understand how envoplakin expression is regulated, we have analyzed the structure of the mouse envoplakin gene and characterized the promoters of both the human and mouse genes. The mouse gene consists of 22 exons and maps to chromosome 11E1, syntenic to the location of the human gene on 17q25. The exon-intron structure of the mouse envoplakin gene is common to all members of the plakin family: the N-terminal protein domain is encoded by 21 small exons, and the central rod domain and the C-terminal globular domain are coded by a single large exon. The C terminus shows the highest sequence conservation between mouse and human envoplakins and between envoplakin and the other family members. The N terminus is also conserved, with sequence homology extending to Drosophila Kakapo. A region between nucleotides -101 and 288 was necessary for promoter activity in transiently transfected primary keratinocytes. This region is highly conserved between the human and mouse genes and contains at least two different positively acting elements identified by site-directed mutagenesis and electrophoretic mobility shift assays. Mutation of a GC box binding Sp1 and Sp3 proteins or a combined E box and Krüppel-like element interacting with unidentified nuclear proteins virtually abolished promoter activity. 600 base pairs of the mouse upstream sequence was sufficient to drive expression of a beta-galactosidase reporter gene in the suprabasal layers of epidermis, esophagus, and forestomach of transgenic mice. Thus, we have identified a regulatory region in the envoplakin gene that can account for the expression pattern of the endogenous protein in stratified squamous epithelia.     

A Family of Novel DNA-Binding Nuclear Proteins Having Polypyrimidine Tract-Binding Motif and Arginine/Serine-Rich Motif

NP220 is a DNA-binding nuclear protein originally cloned from human cell lines. Human NP220 (hNP220) has an arginine/serine-rich motif found in non-small nuclear RNP splicing factors (SR proteins) and shares three domains (MH1, MH2 and MH3) with an acidic nuclear matrix protein, matrin 3. The MH2 domain repeats three times and has homology to the polypyrimidine tract-binding motif of heterogeneous nuclear RNP I/L. NP220 also has a DNA-binding domain and nine repeats of the sequence LVTVDEVIEEEDL (acidic repeat). We have now isolated mouse equivalents of NP220 (mNP220s) and found that NP220s form a family of proteins with four members produced by alternative splicing of a common pre-mRNA. Two longer forms (NP220α and NP220β) have all functional domains mentioned above while two shorter forms (NP220γ and NP220δ) lack the DNA-binding domain and the acidic repeat. The structural aspects of NP220s are distinct from that of the SR proteins but rather resemble U2AF and Tra2 which activate a specific 3′-splicing site of specific genes in response to differentiation-dependent signals.     

Identification of genes encoding receptor-like protein kinases as possible targets of pathogen- and salicylic acid-induced WRKY DNA-binding proteins in Arabidopsis

To understand how plant host genes are regulated during the activation of plant defence responses, we are studying a group of pathogen- and salicylic acid (SA)-induced DNA-binding proteins containing the novel WRKY domain. To identify downstream target genes of these WRKY proteins, we have searched the Arabidopsis genome and identified four closely linked genes on chromosome IV that contain an unusually large number of the W-box sequences [(T)TGAC(C/T)] recognized by WRKY proteins within a few hundred base pairs upstream of their coding regions. All four genes encode proteins characteristic of receptor-like protein kinases (RLK), each consisting of an N-terminal signal sequence, an extracellular receptor domain, a single transmembrane domain and a C-terminal cytoplasmic serine/threonine protein kinase domain. All four RLK genes were induced by treatment with SA or infection by a bacterial pathogen. Studies with one of the RLK genes (RLK4) indicated that a cluster of W-box elements in its promoter region were recognized by both purified WRKY proteins and SA-induced W-box binding activities from SA-treated Arabidopsis plants. Further analysis using the RLK4 gene promoter fused to a reporter gene in transgenic Arabidopsis indicated that the consensus WRKY protein-binding sites in the RLK4 gene promoter were important for the inducible expression of the reporter gene. These results indicate that pathogen- and SA-induced W-box binding proteins regulate not only genes encoding defence proteins with direct or indirect anti-microbial activities, but also genes encoding proteins with regulatory functions.     

Identification and characterization of SIGIRR, a molecule representing a novel subtype of the IL-1R superfamily.

A novel member of the interleukin 1 receptor (IL-1R) superfamily, SIGIRR (single Ig IL-1R-related molecule) was identified in mouse and human. Although it shows the typical conserved motifs that characterize the IL-1R and Toll superfamily, it is structurally and functionally distinct from both. SIGIRR has only one Ig domain in its extracellular portion whereas the IL-1R family contains three Ig folds. An unusually long cytoplasmic domain is reminiscent of the structure of drosophila Toll, yet the SIGIRR peptide sequence is more closely related to IL-1RI. The human SIGIRR gene maps to 11p15. 5 and thus is not located in the same cluster on chromosome 2 that is known to contain four members of the IL-1R family. It failed to bind to the known IL-1-family members and, when co-expressed with the IL-1RI, had no effect on the binding of IL-1 and on subsequent nuclear factor kappaB (NFkappaB) activation. A chimera, in which the SIGIRR intracellular domain was fused to the IL-1R extracellular domain, did not activate NFkappaB unlike similar fusion proteins of other IL-1R related molecules. We conclude that the SIGIRR protein represents a novel subtype of the IL-1R superfamily.     

Interaction of elicitor-induced DNA-binding proteins with elicitor response elements in the promoters of parsley PR1 genes.

PR1 is a pathogenesis-related protein encoded in the parsley genome by a family of three genes (PR1-1, PR1-2 and PR1-3). Loss- and gain-of-function experiments in a transient expression system demonstrated the presence of two fungal elicitor responsive elements in each of the PR1-1 and PR1-2 promoters. These elements, W1, W2 and W3, contain the sequence (T)TGAC(C) and mutations that disrupt this sequence abolish function. Gel shift experiments demonstrated that W1, W2 and W3 are bound specifically by similar nuclear proteins. Three cDNA clones encoding sequence-specific DNA-binding proteins were isolated by South-Western screening and these proteins, designated WRKY1, 2 and 3, also bind specifically to W1, W2 and W3. WRKY1, 2 and 3 are members of the family of sequence-specific DNA-binding proteins, which we call the WRKY family. Treatment of parsley cells with the specific oligopeptide elicitor Pep25 induced a transient and extremely rapid increase in mRNA levels of WRKY1 and 3. WRKY2 mRNA levels in contrast showed a concomitant transient decrease. These rapid changes in WRKY mRNA levels in response to a defined signal molecule suggest that WRKY1, 2 and 3 play a key role in a signal transduction pathway that leads from elicitor perception to PR1 gene activation.     

Identification and characterization of srp1, a gene of fission yeast encoding a RNA binding domain and a RS domain typical of SR splicing factors.

The SR protein family is involved in constitutive and regulated pre-mRNA splicing and has been found to be evolutionarily conserved in metazoan organisms. In contrast, the genome of the unicellular yeast Saccharomyces cerevisiae does not contain genes encoding typical SR proteins. The mammalian SR proteins consist of one or two characteristic RNA binding domains (RBD), containing the signature sequences RDAEDA and SWQDLKD respectively, and a RS (arginine/serine-rich) domain which gave the family its name. We have now cloned from the fission yeast Schizosaccharomyces pombe the gene srp1. This gene is the first yeast gene encoding a protein with typical features of mammalian SR protein family members. The gene is not essential for growth. We show that overexpression of the RNA binding domain inhibits pre-mRNA splicing and that the highly conserved sequence RDAEDA in the RBD is involved. Overexpression of Srp1 containing mutations in the RS domain also inhibits pre-mRNA splicing activity. Furthermore, we show that overexpression of Srp1 and overexpression of the mammalian SR splicing factor ASF/SF2 suppress the pre-mRNA splicing defect of the temperature-sensitive prp4-73 allele. prp4 encodes a protein kinase involved in pre-mRNA splicing. These findings are consistent with the notion that Srp1 plays a role in the splicing process.     

KIN241: a gene involved in cell morphogenesis in Paramecium tetraurelia reveals a novel protein family of cyclophilin–RNA interacting proteins (CRIPs) conserved from fission yeast to man

In this study, we report cloning, by functional complementation of the KIN241 gene involved in Paramecium cell morphogenesis, cortical organization and nuclear reorganization. This gene is predicted to encode a protein of a novel type, comprising a cyclophilin-type, peptidyl-prolyl isomerase domain, an RNA recognition motif, followed by a region rich in glutamate and lysine (EK domain) and a C-terminal string of serines. As homologues of this protein are present in the genomes of Schizosaccharomyces pombe, Caenorhabditis elegans, Drosophila melanogaster, Arabidopsis thaliana and Homo sapiens, the Kin241p predicted sequence defines a new family of proteins that we propose to call 'CRIP', for cyclophilin-RNA interacting protein. We demonstrate that, in Paramecium, Kin241p is localized in the nucleus and that deletion of some nuclear localization signals (NLSs) decreases transport of the protein into the nucleus. No Kin241-1 protein is present in mutant cells, suggesting that the C-terminal serine-rich region is responsible for protein stability.