Magnetism, iron minerals, and life on Mars.

A short critical review is provided on two questions linking magnetism and possible early life on Mars: (1) Did Mars have an Earth-like internal magnetic field, and, if so, during which period and was it a requisite for life? (2) Is there a connection between iron minerals in the martian regolith and life? We also discuss the possible astrobiological implications of magnetic measurements at the surface of Mars using two proposed instruments. A magnetic remanence device based on magnetic field measurements can be used to identify Noachian age rocks and lightning impacts. A contact magnetic susceptibility probe can be used to investigate weathering rinds on martian rocks and identify meteorites among the small regolith rocks. Both materials are considered possible specific niches for microorganisms and, thus, potential astrobiological targets. Experimental results on analogues are presented to support the suitability of such in situ measurements.

Tubulin binding sites on gamma-tubulin: identification and molecular characterization.

gamma-Tubulin is essential to microtubule organization in eukaryotic cells. It is believed that gamma-tubulin interacts with tubulin to accomplish its cellular functions. However, such an interaction has been difficult to demonstrate and to characterize at the molecular level. gamma-Tubulin is a poorly soluble protein, not amenable to biochemical studies in a purified form as yet. Therefore basic questions concerning the existence and properties of tubulin binding sites on gamma-tubulin have been difficult to address. Here we have performed a systematic search for tubulin binding sites on gamma-tubulin using the SPOT peptide technique. We find a specific interaction of tubulin with six distinct domains on gamma-tubulin. These domains are clustered in the central part of the gamma-tubulin primary amino acid sequence. Synthetic peptides corresponding to the tubulin binding domains of gamma-tubulin bind with nanomolar K(d)s to tubulin dimers. These peptides do not interfere measurably with microtubule assembly in vitro and associate with microtubules along the polymer length. On the tertiary structure, the gamma-tubulin peptides cluster to surface regions on both sides of the molecule. Using SPOT analysis, we also find peptides interacting with gamma-tubulin in both the alpha- and beta-tubulin subunits. The tubulin peptides cluster to surface regions on both sides of the alpha- and beta- subunits. These data establish gamma-tubulin as a tubulin ligand with unique tubulin-binding properties and suggests that gamma-tubulin and tubulin dimers associate through lateral interactions.

Demonstration and analysis of tubulin binding sites on centrosomes.

Microtubule nucleation on centrosomes is vital to the establishment of organized microtubule arrays in cells. Despite recent advances, little is known about the sequence of molecular events which leads to microtubule assembly on centrosomes. A putative early step in the nucleation process is interaction of free tubulin dimers with centrosomes. Here, we asked if centrosomes indeed interact in a specific manner with free tubulin dimers. Using lysed cells, we show that centrosomes have a specific capacity to accumulate free tubulin molecules as compared to most other cytoplasmic cell structures. When interphasic lysed cells are incubated with rhodamine-conjugated tubulin, centrosomes emerge as conspicuous sites of tubulin accumulation while other insoluble cytoplasmic cell structures are not stained. In mitotic cells, lysed at various stages of mitosis, fluorescent tubulin stains centrosomes and other mitotic structures, such as the mitotic spindle, the midzone of the cleavage furrow, and the center part of the midbody. Fluorescent tubulin staining of centrosomes in lysed cells is not affected by addition of high concentrations of serum albumin to fluorescent tubulin solutions prior to incubation. In contrast, addition of micromolar concentrations of unlabeled tubulin, to fluorescent tubulin solutions, strongly reduces centrosomal staining. The tubulin binding capacity of centrosomes is conserved following centrosome isolation. Using quantitative methods for analysis of fluorescent tubulin binding on centrosomes, we find that centrosomes contain about 25 000 saturable tubulin binding sites. The apparent dissociation constant of tubulin-centrosome complexes is circa 5 microM. The kinetics of tubulin association with centrosomes are slow, with a half-saturation time of about 3 min and a very slow dissociation rate. Tubulin binding to centrosomes is inhibited at low temperatures, at pH above neutrality, and at NaCl concentrations above 100 mM. Our results suggest that accumulation of tubulin dimers is one intrinsic function of centrosomes. We propose that such a function is not accounted for by the presence of gamma-tubulin on centrosomes and may be an important factor in the regulation of centrosome-dependent microtubule nucleation.

Desmoplakin expression and organization at human umbilical vein endothelial cell-to-cell junctions.

Desmoplakin is an intracellular component of desmosomes which plays a role in the anchorage of intermediate filaments to these structures. We report here that, despite the absence of desmosomes, cultured endothelial cells from human umbilical vein express desmoplakin I and II both at mRNA and protein level. Desmoplakin I/II are found only in the detergent insoluble fraction suggesting that most of the protein is linked to the cytoskeleton. Desmoplakin I/II could be detected by western blot only in long confluent cells even if desmoplakin mRNA levels are unchanged by cell confluency. This suggests that desmoplakin might be stabilized at protein level by its association with junctional components. Immunofluorescence confocal microscopy showed that desmoplakin codistributes with VE-cadherin and plakoglobin along the lateral cell membrane. In contrast, desmoplakin localization was distinct from that of PECAM, an endothelial specific junctional protein localized outside adherence junctions. Endothelial cells do not have keratins but they express vimentin. In confluent cells vimentin forms peripheral filaments which attach to the cell membrane in areas at desmoplakin localization. These data suggest that desmoplakin may participate in the molecular organization of interendothelial junctions by interacting with VE-cadherin and promoting vimentin anchorage. This new type of intercellular junction seems to correspond to the "complexus adhaerentes' described in vivo in lymphatic endothelium.

Identification of vinculin as a pericentriolar component in mammalian cells.

Previous studies have shown that centrosome position and structure can be influenced by actin filaments, that centrosomes can influence actin organization, and that an actin homologue is associated with centrosomes. Such observations suggest the existence of connections between centrosomes and actin networks. In keeping with such observations, we show that the pericentriolar material, a main component of centrosomes, contains vinculin, a well-known component of cell adhesion plaques and of adherens cell junctions. We find that in various cell types, centrosomes are specifically stained by five different anti-vinculin antibodies. In adherent cell lines, these antibodies also stained adhesion plaques, but in thymocytes, a cell type devoid of adhesive structures, such antibodies stained only centrosomes. Isolated centrosomes also reacted with the anti-vinculin antibodies and immunoelectron microscopy showed apparent localization of vinculin in the pericentriolar material. Immunoblot analysis confirmed the presence of vinculin in purified centrosomal protein preparations. In such protein fractions, anti-vinculin antibodies reacted with a single polypeptide with an apparent molecular weight similar to that of vinculin. Stepwise solubilization of centrosomal structures using urea showed that high urea concentrations were required to solubilize centrosomal vinculin, suggesting tight association of vinculin with the pericentriolar material. The identification of vinculin as a component of centrosomes provides a possible molecular basis for interaction between F-actin and centrosomes.

Cell cycle dependent distribution of a centrosomal antigen at the perinuclear MTOC or at the kinetochores of higher plant cells.

Compelling evidence has been obtained in favour of the idea that the nuclear surface of higher plant cells is a microtubule-nucleating and/or organizing site (MTOC), in the absence of defined centrosomes. How these plant MTOC proteins are redistributed and function during the progression of the cell cycle remains entirely unknown. Using a monoclonal antibody (mAb 6C6) raised against isolated calf thymus centrosomes and showing apparent reaction with the plant nuclear surface, we followed the targeted antigen distribution during mitosis and meiosis of higher plants. Immunoblot analysis of protein fractions from Allium root meristematic cell extracts probed with mAb 6C6 reveals a polypeptide of an apparent Mr of 78000. In calf centrosome extracts, a polypeptide of comparable molecular mass is found in addition to a major antigen of Mr 180000 after mAb 6C6 immunoblotting. During mitotic initiation, the plant antigen is prominent on the periphery of the prophase nucleus. When the nuclear envelope breaks down, the antigen suddenly becomes associated with the centromere-kinetochores until late anaphase. In telophase, when the nuclear envelope is being reconstructed, it is no longer detected at the kinetochores but is solely associated again with the nuclear surface. This antigen displays a unique spatial and temporal distribution, which may reflect the pathway of plant protein(s) between the nuclear surface and the kinetochores under cell cycle control. So far, such processes have not been described in higher plant cells. These observations shed light on the putative activity of the plant kinetochore as a protein transporter.(ABSTRACT TRUNCATED AT 250 WORDS)

A monoclonal antibody, raised against mammalian centrosomes and screened by recognition of plant microtubule organizing centers, identifies a pericentriolar component in different cell types.

We have used monoclonal antibodies raised against isolated native calf thymus centrosomes to probe the structure and composition of the pericentriolar material. To distinguish prospective antibodies as specific to conserved elements of this material, we screened clones by their identification of microtubule organizing centers (MTOCs) in different animal and plant cells. Among the clonal antibodies that reacted with MTOCs in both plant and mammalian cells, we describe one (mAb 6C6) that was found to immunostain centrosomes in a variety of bovine and human cells. In cycling cells this signal persisted through the entire cell cycle. Microscopy showed that the mAb 6C6 antigen was a component of the pericentriolar material and this was confirmed by biochemical analysis of centrosomes. Using immunoblot analysis of protein fractions derived from purified components of centrosomes, we have characterized the mAb 6C6 antigen as a 180 kDa polypeptide. We conclude that we have identified a protein component permanently associated with the pericentriolar material. Surprisingly, monoclonal antibody 6C6 also stained other mitotic organelles in mammalian cells, in a cell-cycle-dependent manner. During prometaphase and metaphase the antibody stained both centrosomes and kinetochores. At the onset of anaphase the kinetochore-specific staining dissociated from chromosomes and was subsequently redistributed onto a newly characterized organelle, the telophase disc while the centrosomal stain remained intact. It is not known if the 180 kDa centrosomal protein itself redistributes during mitosis, or if the pattern observed represents other antigens with shared epitopes. The pericentriolar material is thought to be composed of conserved elements, which appeared very early during the evolution of eukaryotes. Our results strongly suggest that mAb 6C6 identifies one of these elements.