Keratin homogeneity in the tail feathers of Pavo cristatus and Pavo cristatus mut. alba.

The keratin structure in the cortex of peacocks' feathers is studied by X-ray diffraction along the feather, from the calamus to the tip. It changes considerably over the first 5 cm close to the calamus and remains constant for about 1m along the length of the feather. Close to the tip, the structure loses its high degree of order. We attribute the X-ray patterns to a shrinkage of a cylindrical arrangement of ß-sheets, which is not fully formed initially. In the final structure, the crystalline beta-cores are fixed by the rest of the keratin molecule. The hydrophobic residues of the beta-core are locked into a zip-like arrangement. Structurally there is no difference between the blue and the white bird.

Perlustrin, a Haliotis laevigata (abalone) nacre protein, is homologous to the insulin-like growth factor binding protein N-terminal module of vertebrates.

The 84-amino-acid-long sequence of perlustrin showed homology of the abalone nacre protein to the N-terminal domain of mammalian insulin-like growth factor binding proteins (IGFBPs). Despite the evolutionary distance between mollusks and mammals, the sequence identity was 40% including 12 conserved cysteines. However, the residues which were suggested recently to bind IGF-II in a complex with IGFBP-5 were conserved only partially. Nevertheless, perlustrin bound human IGFs with K(D) approximately 10(-7) M. This was the same affinity range as measured before for the interaction of isolated IGFBP-5 N-terminal domains with IGFs. Moreover, perlustrin bound bovine insulin with only approximately two- to sevenfold lower affinity than IGFs. Sequence similarity and growth factor binding identified perlustrin unequivocally as a member of the IGFBP family, the first found in an invertebrate biomineral. Nacre is known to contain proteinaceous factors which promote bone formation in vitro and in vivo. Bone contains IGFBPs which influence bone metabolism in many ways by modulating either IGF effects or IGF independently. Thus, perlustrin may provide a first clue at the molecular level to what these two phylogenetically rather distant biomineralization systems have in common.

The amino-acid sequence of the abalone (Haliotis laevigata) nacre protein perlucin. Detection of a functional C-type lectin domain with galactose/mannose specificity.

Perlucin isolated from abalone nacre consists of 155 amino acids including a glycosylated asparagine. The sequence of the first 130 amino acids shows a high similarity to the C-type carbohydrate-recognition domains of asialoglycoprotein receptors and other members of the group of C-type lectins but also a weaker similarity to related proteins without carbohydrate-binding activity. This C-type module is followed by a short C-terminal domain containing two almost identical sequence repeats with a length of 10 amino acids. Solid phase assays show a divalent metal ion-dependent binding of perlucin to (neo)glycoproteins containing D-galactose or D-mannose/D-glucose indicating that perlucin is a functional C-type lectin with broad carbohydrate-binding specificity. Our results also indicate that it may be difficult to predict carbohydrate-binding specificity and the occurrence of alternative binding configurations by amino-acid sequence comparisons and homology modeling.

Imaging microtubules and kinesin decorated microtubules using tapping mode atomic force microscopy in fluids.

The atomic force microscope has been used to investigate microtubules and kinesin decorated microtubules in aqueous solution adsorbed onto a solid substrate. The netto negatively charged microtubules did not adsorb to negatively charged solid surfaces but to glass covalently coated with the highly positively charged silane trimethoxysilylpropyldiethylenetriamine (DETA) or a lipid bilayer of 1,2-dipalmitoyl-3-dimethylammoniumpropane. Using electron beam deposited tips for microtubules adsorbed on DETA, single protofilaments could be observed showing that the resolution is up to 5 nm. Under conditions where the silane coated surfaces are hydrophobic, microtubules opened, presumably at the seam, whose stability is lower than that of the bonds between the other protofilaments. This led to a "sheet" with a width of about 100 nm firmly attached to the surface. Microtubules decorated with a stoichiometric low amount of kinesin molecules in the presence of the non-hydrolyzable ATP-analog 5'-adenylylimidodiphosphate could also be adsorbed onto silane-coated glass. Imaging was very stable and the molecules did not show any scan-induced deformation even after hundreds of scans with a scan frequency of 100 Hz.

Purification and characterization of perlucin and perlustrin, two new proteins from the shell of the mollusc Haliotis laevigata.

Two new proteins, named perlucin and perlustrin, with M(r) 17,000 and 13,000, respectively, were isolated from the shell of the mollusc Halotis laevigata (abalone) by ion-exchange chromatography and reversed-phase HPLC after demineralization of the shell in 10% acetic acid. The sequence of the first 32 amino acids of perlucin indicated that this protein belonged to a heterogeneous group of proteins consisting of a single C-type lectin domain. Perlucin increased the precipitation of CaCO(3) from a saturated solution, indicating that it may promote the nucleation and/or the growth of CaCO(3) crystals. With pancreatic stone protein (lithostathine) and the eggshell protein ovocleidin 17, this is the third C-type lectin domain protein isolated from CaCO(3) biominerals. This indicates that this type of protein performs an important but at present unrecognized function in biomineralization. Perlustrin was a minor component of the protein mixture and the sequence of the first 33 amino acids indicated a certain similarity to part of the much larger nacre protein lustrin A.

Oestradiol regulation of the components of the plasminogen-plasmin system in MDA-MB-231 human breast cancer cells stably expressing the oestrogen receptor.

To understand the hormonal regulation of the components of the plasminogen-plasmin system in human breast cancer, we examined the oestradiol (E2) regulation of plasminogen activators (PAs), namely urokinase-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA), plasminogen activator inhibitor type 1 (PAI-1) and uPA receptor (uPAR), in our model system. We used stable transfectants of the MDA-MB-231 human breast cancer cells that express either the wild-type (S30 cells) or the mutant 351asp-->tyr oestrogen receptor (ER) (BC-2 cells). Northern blot analysis showed that there was a concentration-dependent down-regulation of uPA, tPA and PAI-1 mRNAs by E2. In contrast, uPAR mRNA was not modulated by E2. The pure anti-oestrogen ICI 182,780 was able to block E2 action, indicating that the regulation of these genes is ER mediated. The E2 also inhibited the expression and secretion of uPA, tPA and PAI-1 proteins as determined by enzyme-linked immunosorbent assay (ELISA) in cell extracts (CEs) and conditioned media (CM). Zymography of the CM confirmed the inhibitory effect of E2 on uPA activity. Thus, we now report the regulation of uPA, PAI-1 and tPA by E2 in both mRNA and protein levels in ER transfectants. The association between down-regulation of the uPA by E2 and known E2-mediated growth inhibition of these cells was also explored. Our findings indicate that down-regulation of uPA by E2 is an upstream event of inhibitory effects of E2 on growth of these cells as the addition of exogenous uPA did not block the growth inhibition by E2.

Erythroid cell-specific mRNA stability elements in the alpha 2-globin 3' nontranslated region.

Very little is known about the mechanisms mediating longevities of mRNAs. As a means of identifying potential cis- and trans-acting elements which stabilize an individual mRNA, naturally occurring mutations that decreased stability of the normally long-lived globin mRNA were analyzed. Our previous studies demonstrated that a subset of mutations which allowed the translating ribosome to read through into the alpha 2-globin 3' nontranslated region (NTR) targeted the mutant mRNAs for accelerated turnover in erythroid cells but not in several nonerythroid cell lines (I. M. Weiss and S. A. Liebhaber, Mol. Cell. Biol. 14:8123-8132, 1994). These results suggested that translational readthrough interfered with some feature of the alpha 2-globin 3' NTR required for message stability in erythroid cells. To define the cis-acting sequences which comprise this erythroid cell-specific stability determinant, scanning mutagenesis was performed on the alpha 2-globin 3' NTR, and the stability of each mutant mRNA was examined during transient expression. Three cytidine-rich regions which are required for longevity of the alpha 2-globin mRNA were identified. However, in contrast to the readthrough mutations, base substitutions in these elements destabilize the message through a translation-independent mechanism. To account for these results, we propose that the cis-acting elements form a complex or determinant in the normal alpha 2-globin mRNA which protects the message from degradation in erythroid cells. Disruption of this determinant, by translational readthrough or because mutations in an element prevent or inhibit its formation, targets the message for accelerated turnover in these cells.

Detection and characterization of a 3' untranslated region ribonucleoprotein complex associated with human alpha-globin mRNA stability.

The highly stable nature of globin mRNA is of central importance to erythroid cell differentiation. We have previously identified cytidine-rich (C-rich) segments in the human alpha-globin mRNA 3' untranslated region (alpha-3'UTR) which are critical in the maintenance of mRNA stability in transfected erythroid cells. In the present studies, we have detected trans-acting factors which interact with these cis elements to mediate this stabilizing function. A sequence-specific ribonucleoprotein (RNP) complex is assembled after incubation of the alpha-3'UTR with a variety of cytosolic extracts. This so-called alpha-complex is sequence specific and is not formed on the 3'UTR of either beta-globin or growth hormone mRNAs. Furthermore, base substitutions within the C-rich stretches which destabilize alpha-globin mRNA in vivo result in a parallel disruption of the alpha-complex in vitro. Competition studies with a series of homoribopolymers reveals a striking sensitivity of alpha-complex formation to poly(C), suggesting the presence of a poly(C)-binding activity within the alpha-complex. Three predominant proteins are isolated by alpha-3'UTR affinity chromatography. One of these binds directly to poly(C). This cytosolic poly(C)-binding protein is distinct from previously described nuclear poly(C)-binding heterogeneous nuclear RNPs and is necessary but not sufficient for alpha-complex formation. These data suggest that a messenger RNP complex formed by interaction of defined segments within the alpha-3'UTR with a limited number of cytosolic proteins, including a potentially novel poly(C)-binding protein, is of functional importance in establishing high-level stability of alpha-globin mRNA.

Erythroid cell-specific determinants of alpha-globin mRNA stability.

Although globin mRNAs are considered prototypes of highly stable messages, the mechanisms responsible for their longevity remain largely undefined. As an initial step in identifying potential cis-acting elements or structures which contribute to their stability, we analyzed the defect in expression of a naturally occurring alpha 2-globin mutant, alpha Constant Spring (CS). The CS mutation is a single-base change in the translation termination codon (UAA-->CAA) that allows the ribosome to read through into the 3' nontranslated region (NTR). The presence of CS mRNA in transcriptionally active erythroid precursors and its absence (relative to normal alpha-globin mRNA) in the more differentiated transcriptionally silent erythrocytes suggest that this mutation disrupts some feature of the alpha-globin mRNA required for its stability. Using a transient transfection system, we demonstrate that in murine erythroleukemia cells the CS mRNA is unstable compared with the normal alpha 2-globin mRNA. The analyses of several other naturally occurring and site-directed mutant alpha-globin genes in murine erythroleukemia cells indicate that entry of a translating ribosome into the 3' NTR targets the message for accelerated degradation in erythroid cells. In contrast, both the CS and alpha 2-globin mRNAs are stable in several nonerythroid cell lines. These results suggest that translational readthrough disrupts a determinant associated with the alpha 2-globin 3' NTR which is required for mRNA stability in erythroid cells.

Cartilage-specific 5' end of chick alpha 2(I) collagen mRNAs.

Chondrocytes grown in suspension contain both type I and type II collagen mRNAs, yet synthesize only type II collagen. The inability of chondrocytes to synthesize the alpha 2 subunit of type I collagen, alpha 2(I), results from a severely reduced translation elongation rate (Bennett, V.D., and Adams, S.L. (1987) J. Biol. Chem. 262, 14806-14814). Furthermore, the alpha 2(I) collagen mRNAs from chondrocytes are translated inefficiently in vitro and appear slightly smaller than those from other cells (Focht, R.J., and Adams, S.L. (1984) Mol. Cell. Biol. 4, 1843-1852). These observations suggest that the reduced translation elongation rate may be due to an intrinsic property of the mRNAs. In this report we demonstrate that the alpha 2(I) collagen mRNAs from suspended chondrocytes are 120 bases shorter than those from other cells, and that the first 94 bases of the chondrocyte mRNAs differ from the corresponding region of the calvaria mRNAs. The unique 5' end of the chondrocyte alpha 2(I) collagen mRNAs accounts for their smaller size and may be responsible for the translation elongation defect. Interestingly, the alpha 2(I) collagen mRNAs from chondrocytes grown in monolayer, rather than in suspension, no longer display the cartilage-specific 5' end, suggesting that cell shape and/or adhesion may modulate the structure of the 5' end of the chondrocyte alpha 2(I) collagen mRNAs.