Identification and characterization of SKAT-2, a novel Th2-specific zinc finger gene.

We have identified a novel Kruppel-type zinc finger (ZF) gene, SKAT-2, which is selectively expressed by murine Th2 cells. The protein encoded by this gene has 14 C2H2-type ZF tandemly arrayed at its C terminus and N-terminal SCAN box and KRAB domains. SKAT-2 is tissue restricted in expression at the RNA level, detectable only in brain and at low levels in kidney and spleen and few hematopoietic cell lines. By in situ hybridization, SKAT-2 expression was found to peak in antigen-stimulated CD4(+) T cells after 2-3 days of culture under Th2 but not Th1 biasing conditions. This pattern of expression closely mirrored that of GATA-3 in the same cells. In transient transfection experiments in phorbol 12-myristate 13-acetate/ionomycin-stimulated EL4 cells, SKAT-2 was found to up-regulate the activity of the IL-4 but not the IL-5 promoter, contrasting with the ability of GATA-3 to activate both promoters. This result was confirmed using clones of EL4 cells stably expressing an inducible form of SKAT-2, thus SKAT-2 is a novel Th2-specific gene that may play a role in selective regulation of cytokine genes in T cells.

Differential expression of alpha3 fucosyltransferases in Th1 and Th2 cells correlates with their ability to bind P-selectin.

One of the key control points in the trafficking of the T cell effector subsets, Th1 and Th2, to sites of inflammation is their migration out of the bloodstream. The mechanism by which the cells initially adhere to the endothelium is dependent on the selectin family of adhesion molecules. Only polarised Th1 cells are capable of binding P-selectin despite both Th1 and Th2 cells expressing PSGL-1, the P-selectin ligand. This may be due to a secondary modification of PSGL-1 that is present on Th1 but not Th2 cells. One key modification of PSGL-1 is the alpha3 fucosylation of the O-glycans. To address whether the binding of Th1 and Th2 cells may be regulated by fucosylation, we have studied the expression of the alpha3 fucosyltransferases, FucT-IV and VII, using in vitro differentiated mouse T cells. Messenger RNA levels for both FucT-IV and VII were found to be higher in Th1 than Th2 cells. alpha3 fucosyltransferase enzyme activities were also elevated in Th1 cells. The increased expression of the alpha3 fucosyltransferases in Th1 cells correlated with the ability of Th1, but not Th2, cells to bind to P-selectin. Thus, the regulation of the binding of effector T cells to the endothelium, and subsequent trafficking to inflammatory sites, may be controlled by the fucosylation state of PSGL-1 mediated by the selective expression of the alpha3 fucosyltransferases.

Identification of transcriptionally regulated mRNAs from mouse Schwann cell precursors using modified RNA fingerprinting methods.

We have adopted RNA fingerprinting methods to screen for genes that are rapidly up- or down-regulated during normal mammalian development, comparing mRNA from early (embryo day 12) to late (embryo day 13) mouse Schwann cell precursors. The use of total RNA, a reduction of cDNA template for amplification, the detection of RT-PCR products with a sensitive DNA stain and polyacrylamide gel electrophoresis and rigid selection criteria involving three screening steps are significant improvements on previous methods. Of 19 differentially displayed bands, 15 represented novel genes. The four known cDNA fragments (interleukin enhancer binding factor 1, beta3 subunit of phospholipase C, brain beta-spectrin, and P21 polypeptide) consisted of coding sequences, indicating a high chance of obtaining coding regions. A semiquantitative RT-PCR analysis of three of the four known genes and a cDNA fragment randomly selected from the pool of 15 novel sequences, confirmed that they were regulated between embryo days 12 and 13, as predicted by the display gels. Our results suggest that the combination of methods described here will have wide applicability in studies of other developmental systems where precisely timed changes occur and where only small amounts of RNA can be obtained for analysis.

Oct-6 (SCIP/Tst-1) is expressed in Schwann cell precursors, embryonic Schwann cells, and postnatal myelinating Schwann cells: comparison with Oct-1, Krox-20, and Pax-3.

The POU domain transcription factor Oct-6 (SCIP/Tst-1) is likely to control important stages of Schwann cell development, including the initiation of myelination around birth. Here, we use immunocytochemical and reverse transcriptase-polymerase chain reaction techniques to examine Oct-6 earlier in nerve development, to test the idea that Oct-6 has an additional role in Schwann cell precursors or early embryonic Schwann cells, a possibility raised by previous studies on transgenic mice. Consistent with this, we find low but unambiguous levels of Oct-6 mRNA and protein in Schwann cell precursors of mouse and rat (nerves from 12- and 14-day-old embryos, respectively), with expression levels gradually increasing during early Schwann cell development and towards birth. Unexpectedly, Oct-6 immunoreactivity is clearly present in nuclei of most myelinating cells at least as late as postnatal day 12. Furthermore, many nonmyelinating Schwann cells express Oct-6 in adult life. A comparison of Oct-6 mRNA with other Schwann cell transcription factors-namely, Oct-1, Krox-20, and Pax-3-reveals that each factor exhibits strong developmental regulation and a unique expression pattern in embryonic nerves. Therefore, they are likely to play distinct regulatory roles in early development of the Schwann cell lineage.

Identification of the vinculin-binding site in the cytoskeletal protein alpha-actinin.

Using low-speed sedimentation equilibrium we have established that vinculin binds to alpha-actinin with a Kd of 1.3 x 10(-5) M. Electron microscopy of negatively stained preparations of vinculin revealed spherical particles (diameter 11.2 nm; S.D. 1.7 nm, n = 21), whereas alpha-actinin appeared as a rod-shaped particle (length 33 nm; S.D. 3.3 nm, n = 23). Mixtures of the two proteins contained both 'lollipop'- and 'dumbell'-shaped particles which we interpret as either one or two spherical vinculin molecules associated with the ends of the alpha-actinin rod. We have further defined the vinculin-binding site in alpha-actinin using 125I-vinculin and a gel-blot assay in which proteolytic fragments of alpha-actinin and fragments of alpha-actinin expressed in Escherichia coli were resolved by SDS/PAGE and blotted to nitrocellulose. 125I-vinculin bound to polypeptides derived from the spectrin-like repeat region of alpha-actinin, but did not bind to the actin-binding domain. Binding was inhibited by a 100-fold molar excess of unlabelled vinculin. Using a series of glutathione S-transferase fusion proteins we have mapped the vinculin-binding site to a region toward the C-terminal end of the molecule (alpha-actinin residues 713-749). 125I-vinculin also bound to fusion proteins containing this sequence which had been immobilized on glutathione-agarose beads. The vinculin-binding site is localized in a highly conserved region of the molecule close to the first of two EF-hand calcium-binding motifs.

HIV-1 TAR RNA-binding proteins control TAT activation of translation in Xenopus oocytes.

Human immunodeficiency virus (HIV-1) gene expression is activated by the viral TAT protein that interacts with an RNA sequence, TAR, located at the 5' end of all viral mRNAs. TAT functions primarily as a transcriptional activator in mammalian cells. However, in Xenopus oocytes TAT functions primarily as a translational activator. TAR is an RNA structure comprising a partially base-paired stem, a tripyrimidine bulge in the upper stem, and an unpaired six-nucleotide loop. In vitro, TAT binds directly to the bulge with no requirement for the loop. In vivo, however, mutations in the loop abolish TAT activation of transcription and translation, implying a requirement for TAR-binding cellular factors. We now provide genetic evidence for the presence of two TAR-specific cellular factors in Xenopus oocytes. These factors display independent and mutually exclusive interactions with either the loop or the bulge region of TAR. Furthermore, by using in vivo RNA competition assays we show that the cellular factors regulate the accessibility of the TAT binding site. The fact that Xenopus oocytes contain factors that specifically interact with a human viral RNA sequence might indicate that the TAT/TAR interaction is subverting a conserved pathway in the cell.

An adenosine at position 27 in the human immunodeficiency virus type 1 trans-activation response element is not critical for transcriptional or translational activation by Tat.

Tat protein binds to the trans-activation response (TAR) element of human immunodeficiency virus type 1 RNAs and activates gene expression at the level of transcription in mammalian cell lines and translation in Xenopus oocytes. Certain residues within TAR are important for Tat binding in vitro, including residue A-27, which appears to be able to be modified in a Tat-dependent manner in Xenopus oocytes (L. Sharmeen, B. Bass, N. Sonenberg, H. Weintraub, and M. Groudine, Proc. Natl. Acad. Sci. USA 88:8096-8100, 1991). Activation by Tat in oocytes occurs via a covalent modification of TAR-containing RNA. We have found that in both mammalian cells and Xenopus oocytes, conversion of A-27.U-38 or C-27.G-38 or C-27.G-38 reduces activation. However, conversion to G-27.U-38 or G-27.C-38 had little or no effect on activation, and in oocytes, these mutant RNAs were still covalently modified. These data exclude a specific role for the adenosine at residue 27 for Tat activation but suggest a requirement for a purine at this position.

Mutually exclusive splicing of calcium-binding domain exons in chick alpha-actinin.

We have determined the complete sequence of chick brain alpha-actinin (892 amino acids; 107,644 Da). The sequence differs from that of smooth muscle alpha-actinin only in the region of the first EF-hand calcium-binding motif, where 27 residues in brain alpha-actinin are replaced by just 22 residues in the smooth muscle isoform. This probably accounts for the different calcium sensitivities of the two isoforms with respect to actin binding. Analysis of the gene structure showed that this region of sequence divergence is encoded by two separate exons whose incorporation is mutually exclusive. We have determined the proportion of the two transcripts in various tissues and cell lines using poly(A)+ RNA and a quantitative assay based on the polymerase chain reaction. MRC-5 fibroblasts and HeLa cells express mRNAs encoding both isoforms, whereas Namalwa lymphoblastoid cells, which lack actin stress fibers, express only the non-muscle mRNA. Both isoforms of alpha-actinin became incorporated into stress fibers and cell-matrix junctions when full-length chick alpha-actinin cDNAs were expressed in monkey COS cells. The levels of chick alpha-actinin mRNAs were found to be serum-inducible, suggesting that alpha-actinin may be an early response gene.