The superhelical TPR-repeat domain of O-linked GlcNAc transferase exhibits structural similarities to importin alpha

Addition of N-acetylglucosamine (GlcNAc) is a ubiquitous form of intracellular glycosylation catalyzed by the conserved O-linked GlcNAc transferase (OGT). OGT contains an N-terminal domain of tetratricopeptide (TPR) repeats that mediates the recognition of a broad range of target proteins. Components of the nuclear pore complex are major OGT targets, as OGT depletion by RNA interference (RNAi) results in the loss of GlcNAc modification at the nuclear envelope. To gain insight into the mechanism of target recognition, we solved the crystal structure of the homodimeric TPR domain of human OGT, which contains 11.5 TPR repeats. The repeats form an elongated superhelix. The concave surface of the superhelix is lined by absolutely conserved asparagines, in a manner reminiscent of the peptide-binding site of importin alpha. Based on this structural similarity, we propose that OGT uses an analogous molecular mechanism to recognize its targets.     

Location of a fibronectin domain involved in newt epidermal cell migration

The interaction of migrating newt epidermal cells with the extracellular matrix protein, fibronectin, was studied. Pieces of nitrocellulose coated with intact human plasma fibronectin or proteolytically derived fragments were implanted into wounded limbs so that the coated nitrocellulose served as wound bed for migrating epidermal cells as they attempted to form a wound epithelium. Epidermal cells migrated very poorly on nitrocellulose pieces coated with (a) a 27-kD amino-terminal heparin-binding fragment, (b) a 46-kD gelatin-binding fragment, (c) a combined 33- and 66-kD carboxy-terminal heparin-binding preparation representing peptide sequences in the A and B chains, respectively, or (d) a 31-kD carboxy-terminal fragment from the A chain, containing a free sulfhydryl group. In contrast, epidermal cells readily migrated onto nitrocellulose coated with a mixture of fragments from the middle of the molecule (80-125kD) that bind neither heparin nor gelatin. Attempts to block migration on fibronectin-coated nitrocellulose using IB10, a monoclonal antibody that blocks Chinese hamster ovary cell attachment to fibronectin, were unsuccessful despite saturation of the epitope against which IB10 is directed. In contrast, a polyclonal anti-fibronectin antibody did inhibit migration. These results show that the ability of fibronectin to support newt epidermal cell migration is not shared equally by all regions of the molecule, but is restricted to a domain in the middle third. They also suggest that the site supporting migration is separate and distinct from the site mediating Chinese hamster ovary cell attachment.     

RIP death domain structural interactions implicated in TNF-mediated proliferation and survival

Death domain (DD)-containing proteins are involved in both apoptosis and survival/proliferation signaling induced by activated death receptors. Here, a phylogenetic and structural analysis was performed to highlight differences in DD domains and their key regulatory interaction sites. The phylogenetic analysis shows that receptor DDs are more conserved than DDs in adaptors. Adaptor DDs can be subdivided into those that activate or inhibit apoptosis. Modeling of six homotypic DD interactions involved in the TNF signaling pathway implicates that the DD of RIP (Receptor interacting protein kinase 1) is capable of interacting with the DD of TRADD (TNFR1-associated death domain protein) in two different, exclusive ways: one that subsequently recruits CRADD (apoptosis/inflammation) and another that recruits NFkappaB (survival/proliferation).     

Biochemical studies on a cell surface determinant involved in T-cell proliferation

Previous studies have shown that a monoclonal antibody (TH5.2) recognizes a cell-surface determinant which is involved in the proliferative capability of T cells. The work reported here demonstrates that the T-cell-surface antigen recognized by TH5.2 is a glycoprotein of 55,000 to 60,000 molecular weight. The molecule shows a single molecular weight species upon reduction and denaturation, and it contains only a few percent of tunicamycin-sensitive carbohydrate structures. As shown in sequential immunoprecipitation studies, the TH5.2 antigen is on a molecule distinct from the interleukin-2 (Tac) receptor and the T4 molecule. Cell-surface antigenic modulation experiments indicate that the TH5.2 antigen does not comodulate with, and therefore is distinct from, the T3, T4, T8, and Leu-5 T-cell antigens.     

Genes involved in senescence and immortalization

Senescence is now understood to be the final phenotypic state adopted by a cell in response to several distinct cell physiological processes, including proliferation, oncogene activation and oxygen free radical toxicity. The role of telomere maintenance in immortalization and the roles of p16(INK4A), p19(ARF), p53 and other genes in senescence are being further elucidated. Significant progress continues to be made in our understanding of cellular senescence and immortalization.     

Catalytic domain mutation in CYLD inactivates its enzyme function by structural perturbation and induces cell migration and proliferation

Tumor suppressor cylindromatosis protein (CYLD), which specifically cleaves lysine 63-linked ubiquitin chain from its substrate molecules, contributes to myriad of important cellular events including cellular differentiation, oncogenesis, DNA repair and cell cycle control. It is a ubiquitously expressed protein, which negatively regulates NF-kB and JNK signaling pathways and mediates caspase dependent apoptosis through RIP1 deubiqutination. Germline mutations in CYLD are associated with a rare, hypertrophic skin cancer, termed Familial Cylindromatosis. Catalogue of Somatic Mutations in Cancer database ensembles accumulating CYLD point mutations in multiple benign and malignant tumors. However, the functional role of CYLD mutations and their association with cancer progression remains elusive. In the present report, we have shown that cancer associated mutations impose structural alteration in CYLD which impairs its binding to K63 ubiquitin chain. Here, we conclude that loss of CYLD catalytic activity potentiates its oncogenic gain of function through increased cell survival and migration.     

Dematin exhibits a natively unfolded core domain and an independently folded headpiece domain

Dematin is an actin‐binding protein originally identified in the junctional complex of the erythrocyte plasma membrane, and is present in many nonerythroid cells. Dematin headpiece knockout mice display a spherical red cell phenotype and develop a compensated anemia. Dematin has two domains: a 315‐residue, proline‐rich “core” domain and a 68‐residue carboxyl‐terminal villin‐type “headpiece” domain. Expression of full‐length dematin in E. coli as a GST recombinant protein results in truncation within a proline, glutamic acid, serine, threonine rich region (PEST). Therefore, we designed a mutant construct that replaces the PEST sequence. The modified dematin has high actin binding activity as determined by actin sedimentation assays. Negative stain electron microscopy demonstrates that the modified dematin also exhibits actin bundling activity like that of native dematin. Circular dichroism (CD) and NMR spectral analysis, however, show little secondary structure in the modified dematin. The lack of secondary structure is also observed in native dematin purified from human red blood cells. ¹⁵N‐HSQC NMR spectra of modified dematin indicate that the headpiece domain is fully folded whereas the core region is primarily unfolded. Our finding suggests that the core is natively unfolded and may serve as a scaffold to organize the components of the junctional complex.     

CDK2 differentially controls normal cell senescence and cancer cell proliferation upon exposure to reactive oxygen species

The linker of nucleus and cytoskeleton (LINC) complex, including nesprin-1, has been suggested to be crucial for many biological processes. Previous studies have shown that mutations in nesprin-1 cause abnormal cellular functions and diseases, possibly because of insufficient force transmission to the nucleus through actin filaments (F-actin) bound to nesprin-1. However, little is known regarding the mechanical interaction between the nucleus and F-actin through nesprin-1. In this study, we examined nuclear deformation behavior in nesprin-1 knocked-down endothelial cells (ECs) subjected to uniaxial stretching by evaluating nuclear strain from lateral cross-sectional images. The widths of nuclei in nesprin-1 knocked-down ECs were smaller than those in wild-type cells. In addition, nuclear strain in nesprin-1 knocked-down cells, which is considered to be compressed by the actin cortical layer, increased compared with that in wild-type cells under stretching condition. These results indicate that nesprin-1 knockdown releases the nucleus from the tension of F-actin bound to the nucleus, thereby increasing allowance for deformation before stretching, and that F-actin bound to the nucleus through nesprin-1 causes sustainable force transmission to the nucleus.     

Distant structural homology leads to the functional characterization of an archaeal PIN domain as an exonuclease

Genome sequencing projects have focused attention on the problem of discovering the functions of protein domains that are widely distributed throughout living species but which are, as yet, largely uncharacterized. One such example is the PIN domain, found in eukaryotes, bacteria, and Archaea, and with suggested roles in signaling, RNase editing, and/or nucleotide binding. The first reported crystal structure of a PIN domain (open reading frame PAE2754, derived from the crenarchaeon, Pyrobaculum aerophilum) has been determined to 2.5 A resolution and is presented here. Mapping conserved residues from a multiple sequence alignment onto the structure identifies a putative active site. The discovery of distant structural homology with several exonucleases, including T4 phage RNase H and flap endonuclease (FEN1), further suggests a likely function for PIN domains as Mg2+-dependent exonucleases, a hypothesis that we have confirmed in vitro. The tetrameric structure of PAE2754, with the active sites inside a tunnel, suggests a mechanism for selective cleavage of single-stranded overhangs or flap structures. These results indicate likely DNA or RNA editing roles for prokaryotic PIN domains, which are strikingly numerous in thermophiles, and in organisms such as Mycobacterium tuberculosis. They also support previous hypotheses that eukaryotic PIN domains participate in RNAi and nonsense-mediated RNA degradation.     

Mouse invariant chain gamma exhibits structural homology to both polymorphic subunits of the alpha, beta-core complex of I-Ak antigens

The 3 major constituents of the I-Ak subregion-associated complex alpha, beta and gamma were obtained from splenocytes in homogeneous form by differential isolation methods. alpha, beta and gamma were compared on the primary structural level by enzymatic fragmentation procedures and tryptic peptide map analysis of radiolabeled proteins. The data indicate that the invariant chain gamma exhibits extensive structural homology to the polymorphic beta-light and the alpha-heavy chain. Thus, although not being encoded within the MHC gamma appears to belong structurally to the MHC-encoded class II proteins.     

Calmodulin is involved in regulation of cell proliferation.

A chicken calmodulin (CaM) gene has been expressed in mouse C127 cells using a bovine papilloma virus (BPV)-based vector (BPV-CM). The vector-borne genes produce a mature mRNA of the expected size that is present on cytoplasmic polyribosomes. In clonal cell lines transformed by BPV-CM, expression of the CaM gene produced CaM levels 2- to 4-fold above those observed in cells transformed by BPV alone. Increased intracellular CaM caused a reduction of cell cycle length that is solely due to a reduction in the length of the G1 phase. A comparison of six cell lines revealed a linear relationship between the intracellular CaM concentration and the rate of G1 progression. These data provide the first evidence that specific elevation of CaM levels directly affects the rate of cell proliferation.     

Increasing protein stability using a rational approach combining sequence homology and structural alignment: Stabilizing the WW domain

This study shows that a combination of sequence homology and structural information can be used to increase the stability of the WW domain by 2.5 kcal mol(-1) and increase the T(m) by 28 degrees C. Previous homology-based protein design efforts typically investigate positions with low sequence identity, whereas this study focuses on semi-conserved core residues and proximal residues, exploring their role(s) in mediating stabilizing interactions on the basis of structural considerations. The A20R and L30Y mutations allow increased hydrophobic interactions because of complimentary surfaces and an electrostatic interaction with a third residue adjacent to the ligand-binding hydrophobic cluster, increasing stability significantly beyond what additivity would predict for the single mutations. The D34T mutation situated in a pi-turn possibly disengages Asn31, allowing it to make up to three hydrogen bonds with the backbone in strand 1 and loop 2. The synergistic mutations A20R/L30Y in combination with the remotely located mutation D34T add together to create a hYap WW domain that is significantly more stable than any of the protein structures on which the design was based (Pin and FBP28 WW domains).