Multiple conformations of PEVK proteins detected by single-molecule techniques.

An important component of muscle elasticity is the PEVK region of titin, so named because of the preponderance of these amino acids. However, the PEVK region, similar to other elastomeric proteins, is thought to form a random coil and therefore its structure cannot be determined by standard techniques. Here we combine single-molecule electron microscopy and atomic force microscopy to examine the conformations of the human cardiac titin PEVK region. In contrast to a simple random coil, we have found that cardiac PEVK shows a wide range of elastic conformations with end-to-end distances ranging from 9 to 24 nm and persistence lengths from 0.4 to 2.5 nm. Individual PEVK molecules retained their distinctive elastic conformations through many stretch-relaxation cycles, consistent with the view that these PEVK conformers cannot be interconverted by force. The multiple elastic conformations of cardiac PEVK may result from varying degrees of proline isomerization. The single-molecule techniques demonstrated here may help elucidate the conformation of other proteins that lack a well-defined structure.

Ultrastructure and function of dimeric, soluble intercellular adhesion molecule-1 (ICAM-1).

Previous studies have demonstrated dimerization of intercellular adhesion molecule-1 (ICAM-1) on the cell surface and suggested a role for immunoglobulin superfamily domain 5 and/or the transmembrane domain in mediating such dimerization. Crystallization studies suggest that domain 1 may also mediate dimerization. ICAM-1 binds through domain 1 to the I domain of the integrin alpha(L)beta(2) (lymphocyte function-associated antigen 1). Soluble C-terminally dimerized ICAM-1 was made by replacing the transmembrane and cytoplasmic domains with an alpha-helical coiled coil. Electron microscopy revealed C-terminal dimers that were straight, slightly bent, and sometimes U-shaped. A small number of apparently closed ring-like dimers and W-shaped tetramers were found. To capture ICAM-1 dimerized at the crystallographically defined dimer interface in domain 1, cysteines were introduced into this interface. Several of these mutations resulted in the formation of soluble disulfide-bonded ICAM-1 dimers (domain 1 dimers). Combining a domain 1 cysteine mutation with the C-terminal dimers (domain 1/C-terminal dimers) resulted in significant amounts of both closed ring-like dimers and W-shaped tetramers. Surface plasmon resonance studies showed that all of the dimeric forms of ICAM-1 (domain 1, C-terminal, and domain 1/C-terminal dimers) bound similarly to the integrin alpha(L)beta(2) I domain, with affinities approximately 1.5--3-fold greater than that of monomeric ICAM-1. These studies demonstrate that ICAM-1 can form at least three different topologies and that dimerization at domain 1 does not interfere with binding in domain 1 to alpha(L)beta(2).

Defining fibronectin's cell adhesion synergy site by site-directed mutagenesis.

Fibronectin's RGD-mediated binding to the alpha5beta1 integrin is dramatically enhanced by a synergy site within fibronectin III domain 9 (FN9). Guided by the crystal structure of the cell-binding domain, we selected amino acids in FN9 that project in the same direction as the RGD, presumably toward the integrin, and mutated them to alanine. R1379 in the peptide PHSRN, and the nearby R1374 have been shown previously to be important for alpha5beta1-mediated adhesion (Aota, S., M. Nomizu, and K.M. Yamada. 1994. J. Biol. Chem. 269:24756-24761). Our more extensive set of mutants showed that R1379 is the key residue in the synergistic effect, but other residues contribute substantially. R1374A decreased adhesion slightly by itself, but the double mutant R1374A-R1379A was significantly less adhesive than R1379A alone. Single mutations of R1369A, R1371A, T1385A, and N1386A had negligible effects on cell adhesion, but combining these substitutions either with R1379A or each other gave a more dramatic reduction of cell adhesion. The triple mutant R1374A/P1376A/R1379A had no detectable adhesion activity. We conclude that, in addition to the R of the PHRSN peptide, other residues on the same face of FN9 are required for the full synergistic effect. The integrin-binding synergy site is a much more extensive surface than the small linear peptide sequence.

Characterization of the vasculogenic block in the absence of vascular endothelial growth factor-A.

Vascular endothelial growth factor (VEGF) signaling is required for both differentiation and proliferation of vascular endothelium. Analysis of differentiated embryonic stem cells with one or both VEGF-A alleles deleted showed that both the differentiation and the expansion of endothelial cells are blocked during vasculogenesis. Blood island formation was reduced by half in hemizygous mutant VEGF cultures and by 10-fold in homozygous mutant VEGF cultures. Homozygous mutant cultures could be partially rescued by the addition of exogenous VEGF. RNA levels for the endothelial adhesion receptors ICAM-2 and PECAM were reduced in homozygous mutant cultures, but ICAM-2 RNA levels decreased substantially, whereas PECAM RNA levels remained at hemizygous levels. The quantitative data correlated with the antibody staining patterns because cells that were not organized into vessels expressed PECAM but not ICAM-2. These PECAM+ cell clumps accumulated in mutant cultures as vessel density decreased, suggesting that they were endothelial cell precursors blocked from maturation. A subset of PECAM+ cells in clumps expressed stage-specific embryonic antigen-1 (SSEA-1), and all were ICAM-2(-) and CD34(-), whereas vascular endothelial cells incorporated into vessels were PECAM(+), ICAM-2(+), CD34(+), and SSEA-1(-). Analysis of flk-1 expression indicated that a subset of vascular precursor cells coexpressed PECAM and flk-1. These data suggest that VEGF signaling acts in a dose-dependent manner to affect both a specific differentiation step and the subsequent expansion of endothelial cells. (Blood. 2000;95:1979-1987)

Developmental platelet endothelial cell adhesion molecule expression suggests multiple roles for a vascular adhesion molecule.

Platelet endothelial cell adhesion molecule (PECAM) is used extensively as a murine vascular marker. PECAM interactions have been implicated in both vasculogenesis and angiogenesis. To better understand the role of PECAM in mammalian development, PECAM expression was investigated during differentiation of murine embryonic stem (ES) cells and in early mouse embryos. Undifferentiated ES cells express PECAM, and as in vitro differentiation proceeds previously unidentified PECAM-positive cells that are distinct from vascular endothelial cells appear. PECAM expression is gradually restricted to endothelial cells and some hematopoietic cells of differentiated blood islands. In embryos, the preimplantation blastocyst contains PECAM-positive cells. PECAM expression is next documented in the postimplantation embryonic yolk sac, where clumps of mesodermal cells express PECAM before the development of mature blood islands. The patterns of PECAM expression suggest that undifferentiated cells, a prevascular cell type, and vascular endothelial cells express this marker during murine development. PECAM expression in blastocysts and by ES cells suggests that PECAM may function outside the vascular/hematopoietic lineage.

A single cysteine, Cys-64, is essential for assembly of tenascin-C hexabrachions.

Tenascin-C is a large, multimeric extracellular matrix protein that is found in a variety of tissues and can have profound effects on cell adhesion. It is secreted from cells as a hexamer of six identical chains called a hexabrachion. Disulfide bonding among tenascin subunits mediates intracellular assembly into hexamers. The amino-terminal assembly domain consists of heptad repeats and at least six cysteine residues (Cys-64, -111, -113, -140, -146, -147) that could be involved in multimerization. We have now determined the requirements for these cysteine residues during hexamer assembly. Our results show that only Cys-64 is required to form the hexameric structure. Mutation of Cys-64 to glycine resulted in release of trimer intermediates, which probably form via the heptad repeats, but no hexamers were secreted. In contrast, individual or pairs of mutations of each of the other cysteines had no effect on tenascin hexamer formation, and inclusion of any other cysteine mutations along with C64G did not further disrupt the multimer pattern. However, when all six cysteines were mutated, monomers were the major extracellular form. Together, these results show that trimers are an intermediate of tenascin-C assembly and that Cys-64 is essential for formation of hexabrachions.

Rapid intracellular assembly of tenascin hexabrachions suggests a novel cotranslational process.

Tenascin, an extracellular matrix protein that modulates cell adhesion, exists as a unique six-armed structure called a hexabrachion. The human hexabrachion is composed of six identical 320 kDa subunits and the structure is stabilized by inter-subunit disulfide bonds between amino-terminal segments. We have examined the biosynthesis of tenascin and its assembly into hexabrachions using pulsechase labeling of U-138 MG human glioma cells. Newly synthesized tenascin hexamers are secreted within 60 minutes of translation initiation. Intracellularly, as early as full length tenascin can be detected in pulse-labeled cell lysates, it is already in hexameric form. No precursors, such as monomers, dimers, or trimers, were identified that could be chased into hexamers. This lack of assembly intermediates suggests that nascent tenascin polypeptides associate prior to completion of translation. In contrast, fibronectin monomers in the same lysates are gradually formed into disulfide-bonded dimers. Although hexamer assembly is rapid, the rate-limiting step in secretion appears to be transport to the medial Golgi as endoglycosidase H-resistance was not detected until after a 30 minute chase. These results provide evidence for a novel co-translational mechanism of tenascin assembly which would be facilitated by its length and by the amino-terminal location of the assembly domain.

Genome organization of mouse adenovirus type 1 early region 1: a novel transcription map.

Mouse adenovirus type 1 (MAV-1) genomic DNA from 8.9 to 13.7 map units was sequenced and the early region 1 (E1) transcription map was determined by S1 nuclease, primer extension, and Northern analyses, and cDNA sequencing. The E1 transcription map of MAV-1 had marked dissimilarities from the conserved transcription maps of primate adenovirus E1s. One major E1A and two E1B mRNAs were identified in overlapping transcription units. The single E1A mRNA was composed of three exons; the last exon was coincident with the last exon of the E1B mRNAs. While human adenovirus type 2 (Ad2) utilizes alternate splice donors for the first E1A mRNA exon, MAV-1 does not. Thus, no protein is predicted that would correspond to the Ad2 243 amino acid protein, although MAV-1 can encode a protein similar to the Ad2 289 amino acid protein (A. O. Ball, M. E. Williams, and K. R. Spindler, 1988, J. Virol. 62, 3947-3957). Two spliced E1B mRNAs differed from each other in an intron near the 5' end of the smaller E1B mRNA. This smaller mRNA could encode only the 55K E1B protein, while the larger mRNA could encode both the 21K and 55K E1B proteins.