Tissue zinc distribution in maize seedling roots and its action on growth

Zinc (Zn) distribution over tissues and organs of maize (Zea mays L.) seedlings and its action on root growth, cell division, and cell elongation were studied. Two-day-old seedlings were incubated in the 0.25-strength Hoagland solution containing 2 or 475 μM Zn(NO₃)₂. Zn toxicity was assessed after the inhibition of primary root increment during the first and second days of incubation. The content of Zn was determined by atomic absorption spectrometry in the apical (the first centimeter from the root tip) and basal (the third centimeter from the kernel) root parts. Zn distribution in various tissues was studied by histochemical methods, using a metallochromic indicator zincon and fluorescent indicator Zinpyr-1 and light and confocal scanning fluorescent light microscopy, respectively. To evaluate Zn effects on growth processes, the average length of the meristem; the length of fully elongated cells; the number of meristematic cells in the cortex row; and duration of the cell cycle were measured. When the Zn concentration in the solution was high, the Zn content per weight unit was higher in the basal root part due to its accumulation in lateral root primordial. Zn was also accumulated in both the meristem apoplast and cell protoplasts. In the basal and middle root parts, Zn was detected essentially in all tissues predominantly in the apoplast. Zn inhibited both cell division and elongation. Under Zn influence, the size of the meristem and the number of meristematic cells decreased, which was determined by an increase in the cell cycle duration. The length of the fully elongated cells was also reduced. A comparison of Zn distribution and growth-suppressing activity with other heavy metals studied earlier allows a conclusion that toxic action of heavy metals is mainly determined by physical and chemical properties of their ions and specific patterns of their transport and distribution. As a result, two basic processes determining root growth, e.g., cell division and elongation, could be affected differently.     

Peroxiredoxin-6-interacting proteins in rat olfactory epithelium

Peroxiredoxin 6 (Prx6) belongs to the family of thiol-dependent peroxidases that catalyze the reduction of hydrogen peroxide, organic peroxides, and peroxynitrite. Peroxiredoxins (Prxs) are increasingly recognized as a multi-functional proteins involved in various cellular processes. Accordingly, individual Prxs have been found to interact with multiple partners. Although the list of Prxs-binding proteins is rapidly growing, interactions reported so far show very limited overlap with each other. Our earlier studies indicated that Prx6 is a major cytosolic protein of rat olfactory epithelium and an important component of antioxidant defense system in this tissue. Here we used a combination of biochemical methods including pull-down assay, chemical cross-linking with a tri-functional cross-linker sulfo-SBED, co-immunoprecipitation, and mass spectrometry-based detection to conduct a random search for the Prx6-binding partners in water-soluble extracts from rat olfactory epithelium. Our findings showed that recombinant Prx6 formed complexes with peroxiredoxin 1, cytoskeletal proteins actin and tubulin, metabolic protein glyceraldehyde-3-phosphate dehydrogenase, heat shock proteins 70 and 90, and native Prx6. A common property of the identified proteins is the presence of conserved redox-sensitive Cys residue in their molecules. Novel interactions of rat Prx6 were validated by several independent methods, thus eliminating technical false-positives. However, the conventional methodological approaches to capture reproducibly real physical interactions have intrinsic limitations in distinguishing between randomly and functionally associated proteins, since not all of the naturally occurring protein complexes necessarily bear functional significance. We hypothesize that protein-protein interactions of Prx6 in vivo might induce conformational changes in its molecule, thus increasing the accessibility of the active-site Cys to general cellular reducing agents, such as thioredoxin or glutathione.     

The monolayer–spheres–monolayer cycle: Ultrastructural changes in stem cells

Stem cell sphere formation is applied as a preconditioning treatment prior to transplantation. Here, stem cells (SC) isolated from human subepicardial adipose tissue were analyzed at different stages of the monolayer–spheres–monolayer cycle by transmission electron microscopy. Spheres obtained on a non-adherent surface or through hanging drops gave similar results. At the first two or three passages (stage 1), isolated SC displayed an embryonal cell-like ultrastructure. With increased passage number (stage 2), SC became larger and more electron-dense with a multilobed nucleus, well-developed rough endoplasmic reticulum (RER), well-developed Golgi apparatus, and numerous vacuoles. At 2 h after sphere induction (stage 3), SC gathered into clusters and formed desmosome-like intercellular contacts. Their nuclei possessed a large loose fibrillo-granular nucleolus, the cytoplasm was tightly packed with disintegrated cisternae of RER, and Golgi apparatus was not identified. Twenty-four hours afterward (stage 4), SC in well-formed spheres exhibited a large dense nucleolus and poorly developed Golgi apparatus and RER. One day after sphere dissociation (stage 5), SC looked like embryonal cells and were morphologically similar to the cells of the first stage except for the presence of a large nucleolus and several Golgi complexes. At 48 h after sphere dissociation (stage 6), SC became electron-dense and resembled SC of the second stage, bearing irregular nuclei and cytoplasm that was rich in RER. We interpret these results as SC senescence with increasing passage number after isolation from the tissue or 1 day after sphere dissociation and rejuvenation of the SC just after sphere dissociation. Further research is needed to determine the genetic, biochemical, and physiological parameters of the SC corresponding to morphologically defined distinct stages in order to provide high quality cellular material for cell therapy.     

The effects of lead,nickel, and strontium nitrates on cell division and elongation in maize roots

The effects of Pb, Sr, and Ni nitrates on the root growth, its cell division and elongation were studied. Two-day-old maize seedlings were incubated on the 35 μM Ni(NO₃)₂, 10 μM Pb(NO₃)₂, or 3 mM Sr(NO₃)₂ in the presence or absence of 3 mM Ca(NO₃)₂. Metal toxicity was evaluated after the inhibition of root growth for the first and second days of incubation in comparison with the roots kept on water or Ca(NO₃)₂ solution. The contents of metals were determined in the apical (the first centimeter from the tip) and basal (the third centimeter from the kernel) root parts by voltamperometry and atomic-absorption spectrophotometry. We measured the length of the meristem, the length of the fully elongated cells, counted the mitotic index (MI) in the meristem and the number of meristematic cells in the cortex row; we also calculated duration the cell cycle. In the absence of Ca(NO₃)₂, the metal content in the apical root region was higher than in basal one. In the presence of Ca(NO₃)₂, we observed reverse ratio most pronounced in the case of Pb and Sr. All metals tested markedly reduced MI in the cortex, which was determined by the increase in the cell cycle duration and accompanied by the meristem shortening. These metals affected differently cell division and elongation: Ni inhibited mainly cell division and to a lesser degree their elongation, whereas Sr and Pb affected both cell division and elongation; only Sr treatment resulted in the increased length of the fully elongated cells. In the presence of Ca, all studied growth indices changed less than in the absence of Ca, which was manifested in the less severe suppression of the root growth and was in agreement with the lower accumulation of the metals in the root tips. Possible causes for the heavy metal action on growth are discussed in connection with the specificity of their transport and accumulation.     

Voltage-gated Ca2+ channels in type III taste cells

In the mammalian taste bud, the heterogeneous cell population includes three morphologically distinct types of cells, type I to type III, which are also different in their electrophysiological features. Particularly, voltage-gated (VG) Ca²⁺ channels are functional solely in taste cells of the type III. These channels were studied here with external Ba²⁺ ions as current carriers. It was specifically shown that VG Ba²⁺ currents were almost completely blockable with nifedipine as well as with ionic blockers, such as Cd²⁺, Ni²⁺, and Co²⁺. Kinetic properties of VG Ba²⁺ currents in type III cells and their sensitivity to the blockers indicated that these currents were largely mediated by VG Ca²⁺ channels of the L-type. The expression of genes, which encode pore-forming α1-subunits of Ca²⁺ channels, was analyzed using methods of molecular biology. Among four genes encoding L-type Ca²⁺ channel α1-subunits (Ca _ν 1.1-Ca _ν 1.4), the expression of Ca _ν 1.2 was demonstrated in taste cells.     

Pathogenesis of the inflammatory bowel disease in context of SARS-COV-2 infection

Molecular Biology Reports - To date, the latest research results suggest that the novel severe acute respiratory syndrome-related coronavirus 2 (SARS-CoV-2) can enter host cells directly via the...