Effects of zinc pre-treatment on blood glutathione,serum zinc and kidney histological organisation in male rats exposed to cadmium

The effects of sub-chronic exposure to cadmium (Cd) on the blood glutathione, serum zinc and on the kidney histological organisation in rats as well as the possible protective role of zinc (Zn) are the object of this study. For this purpose, 60 male Wistar rats (8 weeks old) were divided into three groups: the first group was exposed to Cd in the form of CdCl₂, administered in five doses (each of 0.4 mg Cd/kg b.w.) on days 5, 10, 15, 20 and 25, giving a total dose of 2 mg Cd/kg b.w., i.p.; the second group was simultaneously exposed to Zn and Cd with the same timeline and the same doses of Cd as the first group but with, in addition, injections of Zn in the form of ZnCl₂, administered in doses of 0.8 mg Zn/kg b.w., giving a total dose of 4 mg Zn/kg b w, i.p.; a control group received 0.5 mL of physiological saline in an identical manner. Intoxication with Cd was followed by a significant decrease in blood glutathione, increase in oxidized glutathione as well as histological damage in kidneys. Pre-treatment with Zn exhibited a protective role against Cd toxicity with a significant decrease in serum zinc content. This fact may be explained by an excessive use of zinc in metallothionein synthesis as a cadmium detoxification agent.     

Expression profile of maize (Zea mays) scutellar epithelium during imbibition

The scutellum is a shield-shaped structure surrounding the embryo axis in grass species. The scutellar epithelium (Sep) is a monolayer of cells in contact with the endosperm. The Sep plays an important role during seed germination in the secretion of gibberellins and hydrolytic enzymes and in the transport of the hydrolized products to the growing embryo. We identified 30 genes predominantly expressed after imbibition in the Sep as compared to other parts of the scutellum. A high proportion of these genes is involved in metabolic processes. Some other identified genes are involved in the synthesis or modification of cell walls, which may be reflected in the changes of cell shape and cell wall composition that can be observed during imbibition. One of the genes encodes a proteinase that belongs to a proteinase family typical of carnivorous plants. Almost nothing is known about their role in other plants or organs, but the scutellar presence may point to a "digestive" function during germination. Genes involved in the production of energy and the transport of peptides were also identified.     

Insight into Structure-Function Relationships and Inhibition of the Fatty Acyl-AMP Ligase (FadD32) Orthologs from Mycobacteria

Mycolic acids are essential components of the mycobacterial cell envelope, and their biosynthetic pathway is one of the targets of first-line antituberculous drugs. This pathway contains a number of potential targets, including some that have been identified only recently and have yet to be explored. One such target, FadD32, is required for activation of the long meromycolic chain and is essential for mycobacterial growth. We report here an in-depth biochemical, biophysical, and structural characterization of four FadD32 orthologs, including the very homologous enzymes from Mycobacterium tuberculosis and Mycobacterium marinum. Determination of the structures of two complexes with alkyl adenylate inhibitors has provided direct information, with unprecedented detail, about the active site of the enzyme and the associated hydrophobic tunnel, shedding new light on structure-function relationships and inhibition mechanisms by alkyl adenylates and diarylated coumarins. This work should pave the way for the rational design of inhibitors of FadD32, a highly promising drug target.     

The Pks13/FadD32 Crosstalk for the Biosynthesis of Mycolic Acids in Mycobacterium tuberculosis

The last steps of the biosynthesis of mycolic acids, essential and specific lipids of Mycobacterium tuberculosis and related bacteria, are catalyzed by proteins encoded by the fadD32-pks13-accD4 cluster. Here, we produced and purified an active form of the Pks13 polyketide synthase, with a phosphopantetheinyl (P-pant) arm at both positions Ser-55 and Ser-1266 of its two acyl carrier protein (ACP) domains. Combination of liquid chromatography-tandem mass spectrometry of protein tryptic digests and radiolabeling experiments showed that, in vitro, the enzyme specifically loads long-chain 2-carboxyacyl-CoA substrates onto the P-pant arm of its C-terminal ACP domain via the acyltransferase domain. The acyl-AMPs produced by the FadD32 enzyme are specifically transferred onto the ketosynthase domain after binding to the P-pant moiety of the N-terminal ACP domain of Pks13 (N-ACP_Pks13). Unexpectedly, however, the latter step requires the presence of active FadD32. Thus, the couple FadD32-(N-ACP_Pks13) composes the initiation module of the mycolic condensation system. Pks13 ultimately condenses the two loaded fatty acyl chains to produce α-alkyl β-ketoacids, the precursors of mycolic acids. The developed in vitro assay will constitute a strategic tool for antimycobacterial drug screening.Mycolic acids, α-branched and β-hydroxylated fatty acids of unusual chain length (C30-C90), are the hallmark of the Corynebacterineae suborder that includes the causative agents of tuberculosis (Mycobacterium tuberculosis) and leprosy (Mycobacterium leprae). Members of each genus biosynthesize mycolic acids of specific chain lengths, a feature used in taxonomy. For example, Corynebacterium holds the simplest prototypes (C32-C36), called “corynomycolic acids,” which result from an enzymatic condensation between two regular size fatty acids (C16–C18). In contrast, the longest mycolates (C60-C90) are the products of condensation between a very long meromycolic chain (C40-C60) and a shorter α-chain (C22-C26) (1). These so-called “eumycolic acids” are found in mycobacteria and display various structural features present on the meromycolic chain. Eumycolic acids are major and essential components of the mycobacterial envelope where they contribute to the formation of the outer membrane (2, 3) that plays a crucial role in the permeability of the envelope. They also impact on the pathogenicity of some mycobacterial species (4).The first in vitro mycolate biosynthesis assays have been developed using Corynebacterium cell-wall extracts in the presence of a radioactive precursor (5, 6) and have brought key information about this pathway. Yet, any attempt to fractionate these extracts to identify the proteins involved has ended in failure. Later, enzymes catalyzing the formation of the meromycolic chain and the introduction of functions have been discovered with the help of novel molecular biology tools (for review, see Ref. 1), culminating with the identification of the putative operon fadD32-pks13-accD4 that encodes enzymes implicated in the mycolic condensation step in both corynebacteria and mycobacteria (see Fig. 1) (7–9). AccD4, a putative carboxyltransferase, associates at least with the AccA3 subunit to form an acyl-CoA carboxylase (ACC)³ complex that most likely activates, through a C₂-carboxylation step, the extender unit to be condensed with the meromycolic chain (see Fig. 1). In Corynebacterium glutamicum, the carboxylase would metabolize a C16 substrate (8, 10), whereas in M. tuberculosis the purified complex AccA3-AccD4 was shown to carboxylate C24-C26 acyl-CoAs (11). Furthermore, FadD32, predicted to belong to a new class of long-chain acyl-AMP ligases (FAAL) (12), is most likely required for the activation of the meromycolic chain prior to the condensation reaction. At last, the cmrA gene controls the reduction of the β-keto function to yield the final mycolic motif (13) (see Fig. 1).Open in a separate windowFIGURE 1.Proposed scheme for the biosynthesis of mycolic acids. The asymmetrical carbons of the mycolic motif have a R,R configuration. R₁-CO, meromycolic chain; R₂, branch chain. In mycobacteria, R₁-CO = C40-C60 and R₂ = C20-C24; in corynebacteria, R₁-CO = C16-C18 and R₂ = C14-C16; X₁, unknown acceptor of the mycolic α-alkyl β-ketoacyl chains; X₂, unknown acceptor of the mycolic acyl chains.Although the enzymatic properties of the ACC complex have been well characterized (9, 11), those of Pks13 and FadD32 are poorly or not described. Pks13 is a type I polyketide synthase (PKS) made of a minimal module holding ketosynthase (KS), acyltransferase (AT), and acyl carrier protein (ACP) domains, and additional N-terminal ACP and C-terminal thioesterase domains (Fig. 1). Its ACP domains are naturally activated by the 4′-phosphopantetheinyl (P-pant) transferase PptT (14). The P-pant arm has the general function of carrying the substrate acyl chain via a thioester bond involving its terminal thiol group. In the present article we report the purification of a soluble activated form of the large Pks13 protein. For the first time, the loading mechanisms of both types of substrates on specific domains of the PKS were investigated. We describe a unique catalytic mechanism of the Pks13-FadD32 enzymatic couple and the development of an in vitro condensation assay that generates the formation of α-alkyl β-ketoacids, the precursors of mycolic acids.     

Impact of Mapped SSR Markers on the Genetic Diversity of Apricot (<Emphasis Type="Italic">Prunus armeniaca</Emphasis> L.) in Tunisia

The impact of mapped microsatellites on the study of genetic diversity of Tunisian apricot accessions was assessed. The genetic variability of 47 traditional apricot cultivars originating from several areas in Tunisia was investigated with 32 polymorphic microsatellite loci selected for their location throughout the eight linkage groups of Prunus genome. The higher polymorphism and greater transportability of these markers among Prunus species were proved by the expected heterozygosity (He = 0.56) and Shannon’s index of diversity (I = 1.05), indicating that Tunisian apricot germplasm maintained a substantial level of genetic diversity. According to their geographical origin, the genetic differentiation among groups (north, center, and south; Fst = 0.04) was lower, while the gene flow among groups was consequent (Nm = 4.79), attesting a narrow genetic background of apricot in the country. Both unweighted pair-group method with arithmetic mean dendrogram, based on Nei’s genetic distances and factorial correspondence analysis, separated northern cultivars from central and southern cultivars, revealing the same molecular basis of apricot material in the Center and the South of Tunisia. These results revealed the efficiency of mapped markers for genetic variability measurements compared to randomly ones, however, no advantage was observed considering the genetic relationships among studied accessions.