Histochemical methods for detection of heavy metals and strontium in the tissues of higher plants

Elaboration and application of histochemical methods for detection of heavy metals (Cd, Pb, Ni, Zn) and strontium for the purpose of investigating their distribution, accumulation, and translocation within the tissues of higher plants are discussed. Detailed protocols of metal detection with metallochrome indicators dithizone (Cd, Pb), dimethylglyoxime (Ni), sodium rhodizonate (Sr), zincon (Zn), and fluorescent indicator Zinpyr-1 (Zn) by light and fluorescence microscopy are described. Special attention is given to interpretation of the obtained results, advantages and drawbacks of these methods, as well as potential problems associated with histochemical analysis of distribution of heavy metals and strontium.     

Distribution and Toxic Effects of Cadmium and Lead on Maize Roots

Two-day-old seedlings of maize (Zea mays L.) were incubated on Cd and Pb nitrate solutions at the concentrations that inhibited root growth approximately by 50% after two-day-long incubation (LC₅₀; 10^–4 and 10^–3 M, respectively) or completely terminated growth of the primary root after one-day-long incubation (LC; 5 × 10^–4 and 10^–2 M, respectively). Cd and Pb contents were measured using an anodic inversion voltammetric technique in a flow injection system and a histochemical method. At LC₅₀, Cd and Pb were discerned, by histochemical techniques, in all root apical tissues, whereas in the root hair zone, the heavy metals were primarily accumulated in the apoplast of the rhizodermis and cortex and to a lesser extent, in the vascular tissues and parenchyma cells surrounding the metaxylem vessels. Insignificant accumulation of Cd and Pb in the pericycle probably explains why root branching was tolerant to these agents. At LC, Cd and Pb were found in the apoplast of all root tissues, in accordance with the practically complete inhibition of root growth and branching. Irrespectively of Cd and Pb concentrations in the external solution, the metal contents in the root apex exceeded those in the basal region. Procion dyes were used to assess cell death inflicted by Cd and Pb. At LC, the root cap and meristematic cells perished, together with the rhizodermal cells and the outer cortical cells of the root apex, whereas only the rhizodermal cells in the root apical region died at LC₅₀. The evidence that Cd and Pb cross the endodermal barrier at LC presumes that, at lower metal concentrations, the Casparian strip and plasmalemma of the endodermis regulate the transport of these metals into the central cylinder. The authors conclude that the identical barriers control Cd and Pb transport in root tissues.     

Plasmolysis as a Tool to Reveal Lead Localization in the Apoplast of Root Cells

In order to analyze the distribution of lead between cell walls and plasmalemma, two-day-old maize seedlings (Zea mays L.) were incubated for 24 h on a solution of lead nitrate at a concentration causing 50% inhibition of root growth (10^–5 M). Using the histochemical technique (precipitation of lead dithizonate), the distribution of lead in plasmolyzed and nonplasmolyzed cells of the root cortex was compared. This allowed us to separate the lead bound by cell walls from the lead located on the protoplast surface and in the periplasmic space. The plasmolysis was conducted prior to histochemical reaction by the incubation of seedling roots in 0.6 M sucrose solution for 30 min. The lead precipitates were located in cell walls and on the surface of protoplast. A small amount of lead was found in periplasmic space of some cells in root cortex. It is suggested that the lead is bound not only to the cell wall matrix but also to the plasmalemma.     

Junín virus infection activates the type I interferon pathway in a RIG-I-dependent manner

Junín virus (JUNV), an arenavirus, is the causative agent of Argentine hemorrhagic fever, an infectious human disease with 15-30% case fatality. The pathogenesis of AHF is still not well understood. Elevated levels of interferon and cytokines are reported in AHF patients, which might be correlated to the severity of the disease. However the innate immune response to JUNV infection has not been well evaluated. Previous studies have suggested that the virulent strain of JUNV does not induce IFN in human macrophages and monocytes, whereas the attenuated strain of JUNV was found to induce IFN response in murine macrophages via the TLR-2 signaling pathway. In this study, we investigated the interaction between JUNV and IFN pathway in human epithelial cells highly permissive to JUNV infection. We have determined the expression pattern of interferon-stimulated genes (ISGs) and IFN-β at both mRNA and protein levels during JUNV infection. Our results clearly indicate that JUNV infection activates the type I IFN response. STAT1 phosphorylation, a downstream marker of activation of IFN signaling pathway, was readily detected in JUNV infected IFN-competent cells. Our studies also demonstrated for the first time that RIG-I was required for IFN production during JUNV infection. IFN activation was detected during infection by either the virulent or attenuated vaccine strain of JUNV. Curiously, both virus strains were relatively insensitive to human IFN treatment. Our studies collectively indicated that JUNV infection could induce host type I IFN response and provided new insights into the interaction between JUNV and host innate immune system, which might be important in future studies on vaccine development and antiviral treatment.     

A common single nucleotide polymorphism in endoplasmic reticulum aminopeptidase 2 induces a specificity switch that leads to altered antigen processing

Endoplasmic reticulum aminopeptidases 1 and 2 (ERAP1 and ERAP2) cooperate to trim antigenic peptide precursors for loading onto MHC class I molecules and help regulate the adaptive immune response. Common coding single nucleotide polymorphisms in ERAP1 and ERAP2 have been linked with predisposition to human diseases ranging from viral and bacterial infections to autoimmunity and cancer. It has been hypothesized that altered Ag processing by these enzymes is a causal link to disease etiology, but the molecular mechanisms are obscure. We report in this article that the common ERAP2 single nucleotide polymorphism rs2549782 that codes for amino acid variation N392K leads to alterations in both the activity and the specificity of the enzyme. Specifically, the 392N allele excises hydrophobic N-terminal residues from epitope precursors up to 165-fold faster compared with the 392K allele, although both alleles are very similar in excising positively charged N-terminal amino acids. These effects are primarily due to changes in the catalytic turnover rate (k(cat)) and not in the affinity for the substrate. X-ray crystallographic analysis of the ERAP2 392K allele suggests that the polymorphism interferes with the stabilization of the N terminus of the peptide both directly and indirectly through interactions with key residues participating in catalysis. This specificity switch allows the 392N allele of ERAP2 to supplement ERAP1 activity for the removal of hydrophobic N-terminal residues. Our results provide mechanistic insight to the association of this ERAP2 polymorphism with disease and support the idea that polymorphic variation in Ag processing enzymes constitutes a component of immune response variability in humans.     

Nickel Toxicity and Distribution in Maize Roots

A new histochemical method for Ni determination has been developed and employed to study the pattern of Ni distribution in plant tissues. Two-day-old seedlings of maize (Zea mays L.) were transferred onto 15, 20, 25, and 35 M Ni(NO₃)₂ solutions in the presence of 3 mM Ca(NO₃)₂, and Ni localization in shoot and root tissues was investigated at days 2 and 7 of the incubation. Following two days of incubation, Ni was found in all root tissues, and its content increased with the period of exposure and from the tip to the root base. Independent of root region and tissue, Ni content in the protoplasts exceeded that in the cell walls. Ni penetrated the endodermal barrier and accumulated in the endodermis and pericycle to the highest concentration. Ni accumulation in the pericycle restricted root branching. Ni did not affect the final cell length, and the inhibition of root growth resulted from suppressed cell division. In the shoots, Ni content was below the level discerned by the dimethylglyoximine method; we therefore conclude that maize belongs to excluder plants, with their root systems functioning as a barrier limiting heavy metal intake by aboveground organs. The pattern of Ni transport differs from that of Cd and Pb; this difference stands for specific toxic effects of Ni, including an arrest of root branching.     

Comparative Impacts of Heavy Metals on Root Growth as Related to Their Specificity and Selectivity

Two-day-old maize (Zea mays L.) seedlings were incubated on the solutions of Ag, Cd, Pb, Zn, Cu, Tl, Co, and Hg salts (0.001 to 3 g/l). Toxicity of heavy metals was assessed as the inhibition of root growth on the first, second, and third days, the change in the length of the lateral root zone, and the duration of lateral root development from the first division in pericycle to emergence. For all salts under study, the ratio of the lethal concentration to the lowest concentration slowing down root growth was about ten, and growth inhibition was not almost enhanced in the course of three days. With concentrations calculated as g/l, metal toxicity declined in the following order: Cu Tl > Ag > Cd > Hg > Co > Zn > Pb; for molar concentrations, the order was the following: Tl³⁺ > Cu²⁺ > > Ag⁺ > Hg²⁺ Cd²⁺ > Zn²⁺ Pb²⁺ Co²⁺. Duration of lateral root development was least affected by heavy metals. Metal affinity of biological compounds for SH-groups was closely correlated (r = 0.9) with the molar concentration that inhibited primary root growth by 50%. Because of the narrow range of effective concentrations, only slightly increasing inhibition over the exposure time, tolerant root branching, and close relationship between the toxicity and the constant of binding to SH-groups, we conclude that the salts under study exert nonselective inhibition and root growth is slowed down due to the general toxicity of heavy metals rather than selective inhibition of any particular process or processes.