Auxin dependent growth of rhizoids of Chara globularis

Auxin greatly influences plant cell elongation, particularly in the organs of shoots but also in roots. Earlier reports are limited to organ and/or cell growth connected with a mosaic type of cell elongation. The present paper describes auxin sensitivity of polarly growing rhizoid cells of Chara globularis Thuill. where auxin-dependent growth could be observed in two different ways: (1) Auxin had no effect when applied to intact Chara explants with developed thizoids, but decapitated explants reacted to auxin with optimal growth at 1 μ M indole-3-acetic-acid (IAA). (2) N-I-Naphthylphthalamic acid (NPA) at 10 and 100 μ M caused a strong inhibition in rhizoid growth of intact Chara explants. Auxin applied at the same time abolished this inhibition but, due to lack of plant material, endogenous IAA content could not be measured. Chara explants pre-fed with 1-[¹⁴C] IAA from a 3.5 μ M solution for 8 h, then washed and transferred for 11 h to auxin free solution containing 0, 10 or 100 μ M NPA, showed an effect of NPA upon IAA accumulation. Therefore, NPA may inhibit auxin secretion in Chara , 100. Our data are in agreement with earlier results on auxin regulated cell elongation and H⁻-secretion, and show that auxin secretion may also be an essential step in endogenous regulation of polar growth in Chara rhizoids.     

Structure and regulation of the anthranilate synthase genes in Pseudomonas aeruginosa: II. Cloning and expression in Escherichia coli

The genes for the large and small subunits of anthranilate synthase (trpE and trpG, respectively) have been cloned from Pseudomonas aeruginosa PAC174 into E. coli by R-prime formation with the broad-host- range plasmid R68.44. Sequential subcloning into plasmid vectors reduced the active Pseudomonas DNA fragment to a length of 3.1 kb. We obtained evidence that this region contains the promoter for its own expression and retains a vestigial regulatory response to tryptophan scarcity or excess.      

Schiff and pseudo-Schiff reagents: the reactions and reagents of Hugo Schiff,including a classification of various kinds of histochemical reagents used to detect aldehydes

During the 1860’s, Hugo Schiff studied many reactions between amines and aldehydes, some of which have been used in histochemistry, at times without credit to Schiff. Much controversy has surrounded the chemical structures and reaction mechanisms of the compounds involved, but modern analytical techniques have clarified the picture. I review these reactions here. I used molecular modeling software to investigate dyes that contain primary amines representing eight chemical families. All dyes were known to perform satisfactorily for detecting aldehydes in tissue sections. The models verified the correct chemical structures at various points in their reactions and also determined how decolorization occurred in those with “leuco” forms. Decolorization in the presence of sulfurous acid can occur by either adduction or reduction depending on the dye. The final condensation product with aldehyde was determined to be either a C-sulfonic acid adduct on the carbonyl carbon atom or an aminal at the same atom. Based on the various outcomes, I have placed the dyes and their reactions into five categories. Because Hugo Schiff studied the reactions between aldehydes and amines with and without various acids or alcohol, it is only proper to call each of them Schiff reactions that used various types of Schiff reagents.     

Non-canonical localization of RubisCO under high-light conditions in the toxic cyanobacterium Microcystis aeruginosa PCC7806

The frequent production of the hepatotoxin microcystin (MC) and its impact on the lifestyle of bloom-forming cyanobacteria are poorly understood. Here, we report that MC interferes with the assembly and the subcellular localization of RubisCO, in Microcystis aeruginosa PCC7806. Immunofluorescence, electron microscopic and cellular fractionation studies revealed a pronounced heterogeneity in the subcellular localization of RubisCO. At high cell density, RubisCO particles are largely separate from carboxysomes in M. aeruginosa and relocate to the cytoplasmic membrane under high-light conditions. We hypothesize that the binding of MC to RubisCO promotes its membrane association and enables an extreme versatility of the enzyme. Steady-state levels of the RubisCO CO₂ fixation product 3-phosphoglycerate are significantly higher in the MC-producing wild type. We also detected noticeable amounts of the RubisCO oxygenase reaction product secreted into the medium that may support the mutual interaction of M. aeruginosa with its heterotrophic microbial community.     

A new rubisco-like protein coexists with a photosynthetic rubisco in the planktonic cyanobacteria Microcystis

Two genes encoding proteins related to large subunits of Rubisco were identified in the genome of the planktonic cyanobacterium Microcystis aeruginosa PCC 7806 that forms water blooms worldwide. The rbcL(I) gene belongs to the form I subfamily typically encountered in cyanobacteria, green algae, and land plants. The second and newly discovered gene is of the form IV subfamily and widespread in the Microcystis genus. In M. aeruginosa PCC 7806 cells, the expression of both rbcL(I) and rbcL(IV) is sulfur-dependent. The purified recombinant RbcL(IV) overexpressed in Escherichia coli cells did not display CO(2) fixation activity but catalyzed enolization of 2,3-diketo-5-methylthiopentyl-1-phosphate, and the rbcL(IV) gene rescued a Bacillus subtilis MtnW-deficient mutant. Therefore, the Microcystis RbcL(IV) protein functions both in vitro and in vivo and might be involved in a methionine salvage pathway. Despite variations in the amino acid sequences, RbcL(IV) shares structural similarities with all members of the Rubisco superfamily. Invariant amino acids within the catalytic site may thus represent the minimal set for enolization, whereas variations, especially located in loop 6, may account for the limitation of the catalytic reaction to enolization. Even at low protein concentrations in vitro, the recombinant RbcL(IV) assembles spontaneously into dimers, the minimal unit required for Rubisco forms I-III activity. The discovery of the coexistence of RbcL(I) and RbcL(IV) in cyanobacteria, the ancestors of chloroplasts, enlightens episodes of the chaotic evolutionary history of the Rubiscos, a protein family of major importance for life on Earth.     

A mannan binding lectin is involved in cell-cell attachment in a toxic strain of Microcystis aeruginosa

Microcystin, a hepatotoxin that represents a serious health risk for humans and livestock, is produced by the bloom-forming cyanobacterium Microcystis aeruginosa in freshwater bodies worldwide. Here we describe the discovery of a lectin, microvirin (MVN), in M. aeruginosa PCC7806 that shares 33% identity with the potent anti-HIV protein cyanovirin-N from Nostoc ellipsosporum. Carbohydrate microarrays were employed to demonstrate the high specificity of the protein for high-mannose structures containing alpha(1-->2) linked mannose residues. Lectin binding analyses and phenotypic characterizations of MVN-deficient mutants suggest that MVN is involved in cell-cell recognition and cell-cell attachment of Microcystis. A binding partner of MVN was identified in the lipopolysaccharide fraction of M. aeruginosa PCC7806. MVN is differentially expressed in mutants lacking the hepatotoxin microcystin. Additionally, MVN-deficient mutants contain much lower amounts of microcystin than the wild-type cells. We discuss a possible functional correlation between microcystin and the lectin and possible implications on Microcystis morphotype formation. This study provides the first experimental evidence that microcystins may have an impact on Microcystis colony formation that is highly important for the competitive advantage of Microcystis over other phytoplankton species.     

Macromolecular changes caused by formalin fixation and antigen retrieval

Although the mechanics of formalin fixation and antigen retrieval have been studied extensively and reviewed periodically, little attention has been directed toward conformational changes in target molecules. Formaldehyde changes the shape of tissue molecules by appending small hydroxymethyl groups to them. These adducts, in turn, can react with other tissue molecules to form crosslinks, or they can participate in a variety of reactions during tissue processing, including formation of imines, ethoxymethyl adducts, and further crosslinks. Under the influence of alcohol dehydration, fixed DNA may fragment and form a variety of depurination products. The situation becomes even more complex with short fixation times because under these conditions, the dehydrating agent used for tissue processing denatures macromolecules in other ways, most notably through rearrangement of molecular shape to move hydrophobic realms outward and hydrophilic areas inward (hydrophobic inversions). How tissue molecules are modified affects the outcome of immunohistochemical staining and prospects for restoration of antigenicity. Immunoreacitivity may be compromised because epitopes are either sterically hidden, but otherwise unaffected, or they have been altered more directly. Enzyme-based retrieval methods are best suited for the former because they literally snip the molecule apart to reveal the portions of interest. Heat-induced retrieval with buffers can demodify affected epitopes by removing adducts and breaking crosslinks. The choice of temperature and pH is usually critical for optimal retrieval. Effective temperatures are directly related to the strength of bonds-higher temperatures are needed to break stronger bonds. The pH of the retrieval solution determines the charge on the tissue molecule; the goal is to create a charge that causes the demodified molecule to assume a near natural conformation. Rational use of these concepts should lead to better control of immunohistochemical reactions.     

Dyes from a twenty-first century perspective

In June 2008, the Biological Stain Commission sponsored A Seminar on Dyes and Staining the purpose of which was twofold: first, to show that very useful information applicable to biomedical dyes and staining is available from unrelated disciplines and second, to summarize modern thinking on how dyes, solvents, and tissues interact to produce selective staining. In this introduction to the papers from the symposium, we acknowledge that biomedical dye research has declined as newer technologies have gained importance. We should point out, however, that dyes and staining still are vitally important. Moreover, needs abound for innovative studies concerned with dye analysis, synthesis, and mode of action. Concepts and tools from unrelated fields hold promise for significant breakthroughs in many areas of interest.