Cell walls: structures and signals

Cell walls harbor proteins and polysaccharides able to condition the development of a plant. In the past year, genes and enzymes modulating the composition and physical properties of walls have been characterized, and wall composition has been linked to the way a cell interacts with another cell, and to the way in which it differentiates. The sum of the signaling and physical activities of a cell wall may explain much about the control of development.     

Regeneration and maturation of daughter cell walls in the autospore-forming green alga<Emphasis Type="Italic"> Chlorella vulgaris</Emphasis> (Chlorophyta,Trebouxiophyceae)

Cell-wall synthesis in Chlorella vulgaris, an autospore-forming alga, was observed using the cell wall-specific fluorescent dye Fluostain I. The observation suggested two clearly distinguishable stages in cell-wall synthesis: moderate synthesis during the cell-growth process and rapid synthesis at the cell-division stage. We used electron microscopy to examine the structural changes that occurred with growth in the premature daughter cell wall during the cell-growth and cell-division phases. The cell began to synthesize a new daughter cell wall shortly after its release from the autosporangium. A very thin daughter cell wall, with a thickness of about 2 nm, was formed inside the mother cell wall and completely enveloped the outer surface of the plasma membrane of the cell. The daughter cell wall gradually increased in thickness from 2 to 3.8 nm. During the protoplast-division phase in the cell-division stage, the daughter cell wall expanded on the surface of the invaginating plasma membrane of the cleavage furrow, accompanied by active synthesis of the cell wall, which increased in thickness from 3.8 to 6.1 nm. The daughter cell matured into an autospore while completely enclosed by its own thickening (from 6.1 to 17 nm) wall. Finally, the released daughter cell was enclosed by its own cell wall after the mother cell wall burst. The daughter cell with mature wall thickness (17–21 nm) emerged as a small, but complete, autospore.     

Spatial complexity of mechanisms controlling a bacterial cell cycle

Cell cycle progression in Caulobacter is governed by a multilayered regulatory network linking chromosome replication with polar morphogenesis and cell division. Temporal and spatial regulation have emerged as the central themes, with the abundance, activity and subcellular location of key structural and regulatory proteins changing over the course of the cell cycle. An additional layer of complexity was recently uncovered, showing that each segment of the chromosome is located at a specific cellular position both during and after the completion of DNA replication, raising the possibility that this positioning contributes to temporal and spatial control of gene expression.     

Cell polarity, intercellular signalling and morphogenetic cell movements in Myxococcus xanthus

In Myxococcus xanthus morphogenetic cell movements constitute the basis for the formation of spreading vegetative colonies and fruiting bodies in starving cells. M. xanthus cells move by gliding and gliding motility depends on two polarly localized engines, type IV pili pull cells forward, and slime extruding nozzle-like structures appear to push cells forward. The motility behaviour of cells provides evidence that the two engines are localized to opposite poles and that they undergo polarity switching. Several proteins involved in regulating polarity switching have been identified. The cell surface-associated C-signal induces the directed movement of cells into nascent fruiting bodies. Recently, the molecular nature of the C-signal molecule was elucidated and the motility parameters regulated by the C-signal were identified. From the effect of the C-signal on cell behaviour it appears that the C-signal inhibits polarity switching of the two motility engines. This establishes a connection between cell polarity, signalling by an intercellular signal and morphogenetic cell movements during fruiting body formation.     

Plant cell-size control: growing by ploidy?

The size of plant cells is determined by genetic, structural and physical factors as well as by internal and external signals. Our knowledge of the molecular mechanisms of these controls is still rudimentary. Recent studies indicate that ploidy level exerts an important control on cell size. By increasing ploidy, endoreduplication may allow cells to reach extraordinary sizes. This process is widespread in plants and may provide a means to manipulate the cell volume.     

Cell wall synthesis during growth and maturation of Nitella internodal cells

An improved ¹³C-density-labeling method was used to study cell wall synthesis in rapidly expanding, slowly expanding and recently mature internodes of Nitella translucens var axillaris (A.Br.) R.D.W. As cells matured, the rate of wall synthesis slowed and the deposition of cellulose microfibrils changed from a predominantly transverse direction in the primary wall of rapidly expanding internodes to a helicoidal array in the secondary wall of mature internodes. The secondary wall was characterized by relatively higher rates of cellulose synthesis and lower rates of pectin synthesis than the primary wall. The synthesis of xyloglucan also decreased markedly at the transition to secondary wall synthesis, while the synthesis of mannose-rich hemicellulose increased. Even though structural differences were striking between the primary and secondary walls of Nitella, compositional differences between the two types of wall were quantitative rather than qualitative. The authors appreciate the assistance of Martin Yousef with the electron microscopy.     

Chemical diversity through biotransformations

Diversity constitutes an intrinsic property of biosynthesis. This inherent property can be exploited and successfully applied in organic synthesis. Recent advances have been made in many areas, including the use of multifunctional enzymes and catalytic promiscuity, the synthesis of diverse products from a single substrate, the use of different biotransformations to make one product, and the use of in vivo biotransformations.     

Laser microsurgery: a versatile tool in plant (electro) physiology

Summary In plant cells the cell wall is a formidable obstacle in many physiological studies such as patch-clamp measurements and cell labelling with antibodies. Enzymatic digestion of the cell wall, in order to release a protoplast, has a number of disadvantages; therefore we worked out an alternative method to gain access to the plasma membrane. The wall of specialized cells from three higher plant species and one unicellular alga were perforated using the focussed UV light of a nitrogen laser. In order to enhance the absorption of the UV light by the walls, a dye was used that binds specifically to cell wall components. Extrusion of the protoplast or parts thereof was controlled by a regulated gradual decrease of the osmolarity of the solution surrounding the cells. Cytoplasmic streaming and chloroplast circulation were maintained in the protoplasts, demonstrating their viability after the wall perforation with the laser. Continuous deposition of new cell wall material by the polar tip of pollen tubes after surgical removal of the wall at the tip is another demonstration of the viability of the cells. Formation of high resistance seals between the plasma membrane and a patch pipet was surprisingly difficult. The role of Hechtian strands and continuing synthesis of cell wall material in seal formation is further investigated. Other applications for the surgical laser are: fusion of two cells or vacuoles, analysis of the composition of specific parts of the cell wall, and release of the vacuole from an identified cell type for patchclamp studies.Abbreviations CFW calcofluor white - PM plasma membrane     

The functional significance of absence: the chromosomal segment harboring Tp53 is absent from the T55 rat radiation hybrid mapping panel

The T55 rat radiation hybrid (RH) mapping panel has been reported to retain the entire rat genome at retention frequencies between 22% and 37%. However, we found that a small segment of rat chromosome 10 harboring at least four different genes, including Tp53, was completely absent from the panel (retention frequency = 0%). Two other markers located in the vicinity exhibited much reduced retention (2-6%). RH clones are generated by transferring highly fragmented DNA into a recipient cell. There might be a strong selection against the transfer and retention of chromosome segments harboring an intact Tp53, as the action of this gene might prevent proliferation and establishment of the RH clone. Our finding further suggests that unexpected low retention or absence of chromosome segments in an RH panel may represent indications that the segments harbor genes with important functions in cell proliferation control.     

Rv0989c encodes a novel (E)-geranyl diphosphate synthase facilitating decaprenyl diphosphate biosynthesis in Mycobacterium tuberculosis

Mycobacterium tuberculosis (Mtb) has a highly complex cell wall, which is required for both bacterial survival and infection. Cell wall biosynthesis is dependent on decaprenyl diphosphate as a glyco-carrier, which is hence an essential metabolite in this pathogen. Previous biochemical studies indicated (E)-geranyl diphosphate (GPP) is required for the synthesis of decaprenyl diphosphate. Here we demonstrate that Rv0989c encodes the “missing” GPP synthase, representing the first such enzyme to be characterized from bacteria, and which presumably is involved in decaprenyl diphosphate biosynthesis in Mtb. Our investigation also has revealed previously unrecognized substrate plasticity of the farnesyl diphosphate synthases from Mtb, resolving previous discrepancies between biochemical and genetic studies of cell wall biosynthesis.     

TTYH2, a human homologue of the Drosophila melanogaster gene tweety, is located on 17q24 and upregulated in renal cell carcinoma

Using differential display PCR, we identified a novel gene upregulated in renal cell carcinoma. Characterization of the full-length cDNA and gene revealed that the encoded protein is a human homologue of the Drosophila melanogaster Tweety protein, and so we have termed the novel protein TTYH2. The orthologous mouse cDNA was also identified and the predicted mouse protein is 81% identical to the human protein. The encoded human TTYH2 protein is 534 amino acids and, like the other members of the tweety-related protein family, is a putative cell surface protein with five transmembrane regions. TTYH2 is located at 17q24; it is expressed most highly in brain and testis and at lower levels in heart, ovary, spleen, and peripheral blood leukocytes. Expression of this gene is upregulated in 13 of 16 (81%) renal cell carcinoma samples examined. In addition to a putative role in brain and testis, the over-expression of TTYH2 in renal cell carcinoma suggests that it may have an important role in kidney tumorigenesis.     

Formation of cytoplasts from giant protoplasts in culture

Summary Protoplasts isolated from calli ofNicotiana plumbaginifolia can dramatically increase in volume without showing indications of cell wall synthesis. After reaching a critical size, the plasma-rich giant protoplasts show multiple formation of cytoplasts, which are released from the mother cells. The anucleate cytoplasts display the same increase in size as the nucleate protoplasts. Both cell types retain a spherical shape for several months, indicating that no major synthesis of cell wall occurred.     

Cementing the wall: cell wall polysaccharide synthesising enzymes

The year under review has seen the first molecular characterisation, with proof of functionality, of Golgi membrane-bound glycosyltransferase enzymes catalysing the synthesis of non-cellulosic plant cell-wall polysaccharides.     

Lipid function in plant cell polarity

The establishment and maintenance of cell polarity play pivotal roles during plant development. During the past five years, proteins that are required for different aspects of plant cell polarity have been identified. However, the functions of lipids and their interactions with proteins that mediate polarity remained largely unaddressed. Recent genetic studies have discovered cell and tissue polarity mutants that have defects in sterol composition, glycosylphosphatidylinositol-anchored proteins, glycosylphosphatidylinositol biosynthesis and phospholipid signalling. Analyses of the affected gene products have provided a first glance at the roles of lipids in cell polarity signalling, as well as in the trafficking and anchoring of polar proteins.     

Regulation of mitochondrial membrane permeabilization by BCL-2 family proteins and caspases

Mitochondria play an important role in the integration and transmission of cell death signals, activating caspases and other cell death execution events by releasing apoptogenic proteins from the intermembrane space. The BCL-2 family of proteins localize (or can be targeted) to mitochondria and regulate the permeability of the mitochondrial outer membrane to these apoptotic factors. Recent evidence suggests that multiple mechanisms may regulate the release of mitochondrial factors, some of which depend on the action of caspases.     

The ‘interactome’ of the Knr4/Smi1, a protein implicated in coordinating cell wall synthesis with bud emergence in Saccharomyces cerevisiae

The integrity of the Saccharomyces cerevisiae cell wall requires a functional Pkc1–Slt2 MAP kinase pathway that contributes to transient growth arrest, enabling coordination of cell division with cell wall remodelling. How this coordination takes place is still an open question. Recently, we brought evidence that Knr4 protein, whose absence leads to several cell wall defects, may play a role in this function. Here, we show that Knr4 is a monomeric protein that exhibits an aberrant mobility on a SDS-gel electrophoresis and a non-globular structure. Furthermore, Knr4 is an unstable protein that is degraded as cells enter the stationary phase of growth, while its corresponding gene is constitutively expressed. In exponentially growing cells on glucose, Knr4 appeared to be present in a protein complex that migrates with an apparent Mw superior to 250 kDa. Using the TAP–tag methodology, nine potential partners of Knr4 were identified, which could be distributed into three biological processes. A first group consisted of Slt2 and Pil1, two proteins dedicated to cell wall maintenance and biogenesis. The second group comprised four proteins (Bud6, Act1, Cin8 and Jnm1) implicated in the establishment of cell polarity and bud integrity during mitosis. The last group contained four proteins (Asc1, Ubc1, Hsc82 and Gvp36) that probably deal with the stability/degradation of proteins. Deletion analysis revealed that the domain of interaction covered 2/3 of the Knr4 sequence on the N-terminal side. Moreover, the replacement of the two in vivo phosphorylated Ser²⁰⁰ and Ser²⁰³ by alanines led to a mutated protein with reduced protein interactions and a weaker complementation ability towards knr4 null mutant phenotypes. These results together with previous data from genome scale two-hybrid and synthetic interaction screens support the notion that Knr4 is a regulatory protein that participates in the coordination of cell wall synthesis with bud emergence, and that this function may be modulated by phosphorylation of this protein.     

Virus-like particles as vaccines and vessels for the delivery of small molecules

Virus-like particles (VLPs) structurally mimic the viral capsid and have therefore been extensively, and quite successfully, used as vaccine and viral serology reagents. The ability of VLPs to include nucleic acids and small molecules has also made them novel vessels for gene and drug delivery. The regular, repetitive surface of VLPs has been exploited as a template for nanoscale synthesis. Recent progress has been made in the development of several virus models.     

Lysis of growing fissin-yeast cells induced by aculeacin A,a new antifungal antibiotic

Cells of Schizosaccharomyces pombe grown in the presence of aculeacin A, a peptide antibiotic, were lysed resulting the death of cells. Under high osmolarity, the cellular lysis induced by aculeacin A was considerably reduced. The use of synchronous-culture systems distinguished cell elongation from cell division revealed that the sites of aculeacin A-induced lysis on the fission yeast were the end(s) and the cell plate region, corresponded to the regions of the cell wall synthesis. Aculeacin A-resistant survivors exhibited morphological alterations which were swollen at one or both ends of the cell and appeared drumstick or dumbbel like; the wall of the bulge region was observed to be stained with a fluorescent brightener, as well as that of the cell plate region. These effects of aculeacin A are discussed as compared with effects of 2-deoxy-D-glucose.