Low temperature phototransformations of protochlorophyll(ide) in etiolated leaves

By methods of difference and derivative spectroscopy it was shown that in etiolated leaves at 77 K three photoreactions of P650 protochlorophyllide take place which differ in their rates and positions of spectral maxima of the intermediates formed in the process: P650R668, P650R688, and P650R697. With an increase of temperature up to 233 K, in the dark, R688 and R697 are transformed into the known chlorophyllide forms C695/684 and C684/676, while R668 disappears with formation of a shorter wavelength form of protochlorophyllide with an absorption maximum at 643–644 nm.Along with these reactions, at 77 K phototransformations of the long-wave protochlorophyllide forms with absorption maxima at 658–711 nm into the main short-wave forms of protochlorophyllide are observed. At 233 K in the dark this reaction is partially reversible. This process may be interpreted as a reversible photodisaggregation of the pigment in vivo.The mechanism of P650 reactions and their role in the process of chlorophyll photobiosynthesis are discussed.Abbreviations P650 protochlorophyll(ide) with absorption maximum at 650 nm - C697/684 chlorophyllide with fluorescence maximum at 695 nm and absorption maximum at 684 nm - R697 intermediate with absorption maximum at 697 nm     

The role of a long-wavelength pigment form in the chlorophyll biosynthesis

Photoconversion of protochlorophyllide₆₅₀ form was observed in etiolated leaves illuminated with long-wavelength—690 nm—light. This process showed Shibata shift and was found to have a strong temperature dependence between 20 and –40°C. The low rate of reaction, the strong temperature dependence and calculations on the spectral overlap integral of absorption and fluorescence bands in this spectral region indicate that the phototransformation of the 650 nm form of protochlorophyllide may be caused by a back energy migration from a long-wavelength pigment form absorbing around 690 nm; this pigment form is probably a long-wavelength form of protochlorophyll/ide.     

The isolation, identification and characterization of sulfated glycosaminoglycans synthesized in vitro by human eosinophils

Human eosinophils were purified to greater than 92% using 16-30% metrizamide gradients, and these cells cultured for up to 72 h in vitro to label sulfated glycosaminoglycans. Over 90% of the sulfated glycosaminoglycan-containing material was extracted in 4 M guanidine HCl and had a hydrodynamic size similar to a glycosaminoglycan marker with an approximate average molecular weight of 60,000. Treatment of this salt-extracted 35S-labeled glycosaminoglycan-containing material with 0.5 M NaOH resulted in a change in mass to approx. 20,000 daltons, suggesting that the larger molecules were proteoglycans with side chains with an approximate molecular weight of 20,000. These salt extracted presumptive 35S-labeled proteoglycans were protease insensitive and behaved in a highly charged fashion on DEAE-cellulose. The composition of 35S-labeled glycosaminoglycans from human eosinophils as identified using selected polysaccharides was 70-81% chondroitin 4-sulfate, 9-12% chondroitin 6-sulfate, and 5-12% dermatan sulfate. The predominance of chondroitin 4-sulfate in human eosinophils is similar to the predominance of chondroitin 4-sulfate in human neutrophils and human platelets.     

Leptospira distribution in the soil of a natural focus of the infection (an attempt at the radioisotopic labelling of infected voles)]

The mass radioisotope (32P) labelling of all tundra voles excreting Zeptospira, infected urine was carried out over the area of 1 ha, and the results of the experiment analyzed by the method of planar coherent graphs, showed the irregular (spotted) distribution of "infected spots", i. e. soil patches contaminated by Zeptospira. The borders of individual small foci of infection did not coincide with the outlines of soil and vegetational divisions of the area. The spatial structure of the "extraorganismic" part of the Zeptospira population was originally formed by the carriers and thus determined by their mobility, their manner of using the territory. Later this structure was changed by selective elimination under the influence of living conditions for Zeptospira in the soil. The "infected spots", subjected to such selection, seem to be capable of constantly sustaining Zeptospira; the presence of these organisms is also due to the fact that they are regularly added into the soil with urine excreted by the carriers visiting the same spots of their territory.     

Participation of Free Radicals in Photoreduction of Protochlorophyllide to Chlorophyllide in an Artificial Pigment–Protein Complex

The primary stages of protochlorophyllide phototransformation in an artificially formed complex containing heterologously expressed photoenzyme protochlorophyllide-oxidoreductase (POR), protochlorophyllide, and NADPH were investigated by optical and ESR spectroscopy. An ESR signal (g = 2.002; H = 1 mT) appeared after illumination of the complex with intense white light at 77 K. The ESR signal appeared with simultaneous quenching of the initial protochlorophyllide fluorescence, this being due to the formation of a primary non-fluorescent intermediate. The ESR signal disappeared on raising the temperature to 253 K, and a new fluorescence maximum at 695 nm belonging to chlorophyllide simultaneously appeared. The data show that the mechanism of protochlorophyllide photoreduction in the complex is practically identical to the in vivo mechanism: this includes the formation of a short-lived non-fluorescent free radical that is transformed into chlorophyllide in a dark reaction.     

Root system hydraulic conductivity in species with contrasting root anatomy

Previous research suggested that the hydraulic properties of root systems of intact plants could be described by two parameters: the hydraulic conductivity (Lpr) or the slope of the flow-density/water potential gradient relationship, and the offset or minimum water potential gradient required to induce flow. In this study Lpr and offset were correlated with anatomical features of the root radial path in plants with contrasting root anatomy. Two woody and three herbaceous species were examined which exhibit a range of root anatomical features: Asparagus densiflorus (Kunth) Jessop (asparagus), Dendrobium superbum Rchb. f. (dendrobium), Glycine max (L.) Merr. (soybean), Prunus persica (L.) Batsch. (peach), Citrus aurantium L. (sour orange). Lpr varied about 8-fold, and the offset varied about 6-fold among the five species. Lpr was inversely related to root diameter (r²0.39) and cortex width (r²0.55), suggesting that species with thinner roots or roots with a thin cortex had the highest Lpr. Further observations suggested that the cortex width was a stronger determinant of Lpr than root diameter. However, the offset was not correlated with root diameter, stele diameter or cortex width, but was >2-fold higher in species having an exodermis in the root radial path (sour orange, asparagus, and dendrobium) compared to those lacking an exodermis (peach and soybean). The data on root Lr obtained were similar to those given in the literature for both intact plants and excised roots which have been measured with different techniques. It is concluded that Lpr and offset, which describe the flow-water potential relationship for intact root systems, are related to differences in the root cortex; specifically, its thickness and the presence/absence of a suberized exodermis. Hence, these anatomical differences may, in part, cause the variability in root hydralic properties that exists among plant species.     

The chemokine receptor CXCR3 and its splice variant are expressed in human airway epithelial cells

Activation of the chemokine receptor CXCR3 by its cognate ligands induces several differentiated cellular responses important to the growth and migration of a variety of hematopoietic and structural cells. In the human respiratory tract, human airway epithelial cells (HAEC) release the CXCR3 ligands Mig/CXCL9, IP-10/CXCL10, and I-TAC/CXCL11. Simultaneous expression of CXCR3 by HAEC would have important implications for the processes of airway inflammation and repair. Accordingly, in the present study we sought to determine whether HAEC also express the classic CXCR3 chemokine receptor CXCR3-A and its splice variant CXCR3-B and hence may respond in autocrine fashion to its ligands. We found that cultured HAEC (16-HBE and tracheocytes) constitutively expressed CXCR3 mRNA and protein. CXCR3 mRNA levels assessed by expression array were approximately 35% of beta-actin expression. In contrast, CCR3, CCR4, CCR5, CCR8, and CX3CR1 were <5% beta-actin. Both CXCR3-A and -B were expressed. Furthermore, tracheocytes freshly harvested by bronchoscopy stained positively for CXCR3 by immunofluorescence microscopy, and 68% of cytokeratin-positive tracheocytes (i.e., the epithelial cell population) were positive for CXCR3 by flow cytometry. In 16-HBE cells, CXCR3 receptor density was approximately 78,000 receptors/cell when assessed by competitive displacement of 125I-labeled IP-10/CXCL10. Finally, CXCR3 ligands induced chemotactic responses and actin reorganization in 16-HBE cells. These findings indicate constitutive expression by HAEC of a functional CXC chemokine receptor, CXCR3. Our data suggest the possibility that autocrine activation of CXCR3 expressed by HAEC may contribute to airway inflammation and remodeling in obstructive lung disease by regulating HAEC migration.     

Integrative processes in modern epidemiology

The integration of achievements in population ecology and the molecular genetics of pathogenic microorganisms into nowadays epidemiology of infectious diseases and the formation of its corresponding trends are discussed. The decisive role of highly complicated key problems of general epidemiology, such as the regularities of the autochthonous existence of pathogenic bacteria in the environment, the mechanisms of the pathogenicity regulation of infective agents and the formation of their epidemic variants, the mechanisms of the prolonged reservation of pathogenic bacteria at interepidemic (interepizootic) periods, the mechanisms of transformation of active (vegetative) and dormant forms in bacterial populations at different stages of epidemic and epizootic cycles, is demonstrated. The detection and analysis of such processes, and especially their latent mechanisms, become possible with the use of new concepts and methodological approaches, highly productive for the progress of epidemiology.