Germination ofMusa velutina seeds: Comparison ofin vivo andin vitro systems

Summary In the genusMusa, germination is extremely variable and relatively difficult. Even more difficulties are faced when producing hybrids. The seed yield of hybrids in breeding programs is usually low and often, to ensure the viability and survival of seeds, it is necessary to attempt to germinate a large excess of these seeds. In this context,in vitro embryo culture might be an invaluable tool for obtaining desirable hybrid plants in a short time. Seeds ofMusa velutina were sown in seed trays in a peat-based mixture. Thein vivo seed germination reached 78% but only after 9 mo. Because of this delayed and intermittent germination, embryos were excised from seeds and inoculated onto half-strength Murashige and Skoog (1962) medium, with or without supplementation with various concentrations of gibberellic acid. Light and dark conditions were also used to test their effect on embryo germination. After 2 wk, 82% of embryos germinated in the dark on medium containing 0.1 μM gibberellic acid. Addition of gibberellic acid increased the shoot length and root number over the gibberellic acid-free treatment. Similarly, dark conditions gave a significant increase over light conditions for all the parameters except root number where light or dark conditions did not make any difference. Thus, the present study highlights the importance of various components of thein vitro culture ofMusa embryos and the advantage over direct use of greenhouse-sown seeds both in terms of the time taken to germinate and the final percentage.     

Immunobiological studies with mycobacterial ribonucleic acid-protein complex: Part II--Mechanism of protective immunity against experimental tuberculosis.

Passive transfer of protective antituberculous immunity against LD50 dose of M. tuberculosis H37Rv was found to be mainly mediated by immune T-cells harvested from spleens of donor mice immunized with Myc. RNA-P-FIA complexes as monitored by indices of percent survival, root specific lung weight, lung density and by bacterial enumeration from different organs. Treatment of immune T-cells with anti-Thy 1.2. monoclonal antibodies plus complement prior to passive transfer, completely abrogated its protective effect thereby confirming their protective nature. Passive transfer of immune sera as well as immune T + B cells did not induce any enhancement in protective immunity.     

Group A streptococcal surface GAPDH, SDH, recognizes uPAR/CD87 as its receptor on the human pharyngeal cell and mediates bacterial adherence to host cells

Streptococcal surface dehydrogenase (SDH) is a multifunctional, anchorless protein present on the surface of group A Streptococcus (GAS). It plays a regulatory role in GAS-mediated intracellular signaling events in human pharyngeal cells. Using ligand-binding assays, we have identified an approximately 55 kDa protein as an SDH-specific receptor protein on the surface of Detroit human pharyngeal cells. LC-MS/MS analyses identified this SDH-binding pharyngeal cell-surface-exposed membrane-bound protein as uPAR (urokinase plasminogen activator receptor)/CD87. Ligand-binding assays also revealed that only the N-terminal domain (D1) of uPAR bound to SDH. uPAR-D1 more specifically bound to the C-terminal alpha-helix and two immediate flanking regions of the S-loop of the SDH molecule. Site-directed mutagenesis in GAS resulting in SDH with altered C-terminal ends, and the removal of uPAR from pharyngeal cells by phosphatidylinositol-phopsholipase C treatment decreased GAS ability to adhere to pharyngeal cells. When compared to uninfected Detroit pharyngeal cells, GAS-infected pharyngeal cells showed a transient but a significant increase in the expression of uPAR-specific mRNA, and a prolonged recycling process of uPAR on the cell surface. Together, these results indicate that the specific streptococcal surface protein-pharyngeal cell receptor interaction mediated by SDH and uPAR is modulated during GAS infection of human pharyngeal cells. This interaction significantly contributes to bacterial adherence and thus may play a significant role in GAS pathogenesis by regulating intracellular signaling events in pharyngeal cells.     

Metal accumulation in two contiguous eutrophic peri-urban lakes,Chivero and Manyame,Zimbabwe

Concentrations of aluminium, cadmium, chromium, cobalt, copper, iron, lead, nickel and zinc were determined in surface water, benthic sediments, and the gills, liver and stomach muscle tissues of Oreochromis niloticus and Clarias gariepinus in peri-urban lakes Chivero and Manyame, Zimbabwe. Five sites were sampled in each lake once per month in November 2015, February, May, August and November 2016. Pollution load index detected no metal contamination, whereas the geo-accumulation index reflected heavy to extreme sediment pollution, with Fe, Cd, Zn, Cr, Ni and Cu present in both lakes. Significant spatial temporal variations were detected for Al, Cr, Cu and Pb across sites within and between the two lakes. High Fe, Al and Cr concentrations in water and sediments in lakes Chivero and Manyame derive from geogenic background sources in addition to anthropogenic loads and intensity. Elevated concentrations of Al, Pb, Cu, Cd, Fe and Zn detected in gills, liver and stomach tissue of catfish corroborate concentrations in water and sediments, and pose the highest ecological and health risk for hydrobionts in lakes Chivero and Manyame. Contiguity of peri-urban lakes exposes them to similar threats, necessitating creative water management strategies, which ensure ecological continuity.     

Amino acid depletion modulates vascular endothelial growth factor production during the life span of human vascular smooth muscle cells

The role of nutrient supply in the replicative capacity and secretory phenotype of cultured human diploid cells is unclear. We examined the relationship between amino acid privation, the secretion of vascular endothelial growth factor (VEGF) and growth phenotype of vascular smooth muscle cells (VSMC), and endothelial cells. Cultures of VSMCs, but not endothelial cells, were growth inhibited by exposure to medium that was 75% deficient in leucine, methionine, arginine, and cysteine over two passages. Exposed VSMC cultures exhibited an increased vulnerability to apoptosis. The maximal cumulative population doubling of the exposed cells was reduced significantly compared with the control cells (25.7 ± 2.0 doublings vs. 27.9 ± 2.1 doublings; P < 0.03). Constitutive VEGF production first became evident in the later passages of the exposed and nonexposed cell cultures. However, production of VEGF was 17-fold greater in the exposed cultures at the tenth passage (P < 0.001). The replicative capacity and constitutive production of VEGF in VSMCs in culture may be programmed by transient privation of amino acids. These observations are relevant to new concepts concerning the pathogenesis of vascular disease. J. Cell. Physiol. 176:359–364, 1998. © 1998 Wiley-Liss, Inc.     

Defining the Structural Basis of Human Plasminogen Binding by Streptococcal Surface Enolase

The flesh-eating bacterium group A Streptococcus (GAS) binds and activates human plasminogen, promoting invasive disease. Streptococcal surface enolase (SEN), a glycolytic pathway enzyme, is an identified plasminogen receptor of GAS. Here we used mass spectrometry (MS) to confirm that GAS SEN is octameric, thereby validating in silico modeling based on the crystal structure of Streptococcus pneumoniae α-enolase. Site-directed mutagenesis of surface-located lysine residues (SEN^{K252 + 255A}, SEN^K304A, SEN^K334A, SEN^K344E, SEN^K435L, and SEN^Δ434–435) was used to examine their roles in maintaining structural integrity, enzymatic function, and plasminogen binding. Structural integrity of the GAS SEN octamer was retained for all mutants except SEN^K344E, as determined by circular dichroism spectroscopy and MS. However, ion mobility MS revealed distinct differences in the stability of several mutant octamers in comparison with wild type. Enzymatic analysis indicated that SEN^K344E had lost α-enolase activity, which was also reduced in SEN^K334A and SEN^Δ434–435. Surface plasmon resonance demonstrated that the capacity to bind human plasminogen was abolished in SEN^{K252 + 255A}, SEN^K435L, and SEN^Δ434–435. The lysine residues at positions 252, 255, 434, and 435 therefore play a concerted role in plasminogen acquisition. This study demonstrates the ability of combining in silico structural modeling with ion mobility-MS validation for undertaking functional studies on complex protein structures.Streptococcus pyogenes (group A Streptococcus, GAS)⁸ is a common bacterial pathogen, causing over 700 million human disease episodes each year (1). These range from serious life-threatening invasive diseases including necrotizing fasciitis and streptococcal toxic shock-like syndrome to non-invasive infections like pharyngitis and pyoderma. Invasive disease, in combination with postinfection immune sequelae including rheumatic heart disease and acute poststreptococcal glomerulonephritis, account for over half a million deaths each year (1). Although a resurgence of GAS invasive infections has occurred in western countries since the mid-1980s, disease burden is much greater in developing countries and indigenous populations of developed nations, where GAS infections are endemic (2–4).GAS is able to bind human plasminogen and activate the captured zymogen to the serine protease plasmin (5–17). The capacity of GAS to do this plays a critical role in virulence and invasive disease initiation (3, 17–19). The plasminogen activation system in humans is an important and highly regulated process that is responsible for breakdown of extracellular matrix components, dissolution of blood clots, and cell migration (20, 21). Plasminogen is a 92-kDa zymogen that circulates in human plasma at a concentration of 2 μm (22). It consists of a binding region of five homologous triple loop kringle domains and an N-terminal serine protease domain that flank the Arg⁵⁶¹–Val⁵⁶² site (23), where it is cleaved by tissue plasminogen activator and urokinase plasminogen activator to yield the active protease plasmin (20, 23). GAS also has the ability to activate human plasminogen by secreting the virulence determinant streptokinase. Streptokinase forms stable complexes with plasminogen or plasmin, both of which exhibit plasmin activity (20, 24). Activation of plasminogen by the plasmin(ogen)-streptokinase complex circumvents regulation by the host plasminogen activation inhibitors, α₂-antiplasmin and α₂-macroglobulin (11, 20). GAS can bind the plasmin(ogen)-streptokinase complex and/or plasmin(ogen) directly via plasmin(ogen) receptors at the bacterial cell surface (6). These receptors include the plasminogen-binding group A streptococcal M-like protein (PAM) (25), the PAM-related protein (19), glyceraldehyde-3-phosphate dehydrogenase (GAPDH; also known as streptococcal plasmin receptor, Plr, or streptococcal surface dehydrogenase) (9, 26), and streptococcal surface enolase (SEN or α-enolase) (27). Interactions with these GAS receptors occurs via lysine-binding sites within the kringle domains of plasminogen (6).In addition to its ability to bind human plasminogen, SEN is primarily the glycolytic enzyme that converts 2-phosphoglycerate to phosphoenolpyruvate (27–29). SEN is abundantly expressed in the cytosol of most bacterial species but has also been identified as a surface-located protein in GAS and other bacteria including pneumococci, despite lacking classical cell surface protein motifs such as a signal sequence, membrane-spanning domain, or cell-wall anchor motif (27, 28, 30, 31). The interaction between SEN and plasminogen is reported to be facilitated by the two C-terminal lysine residues at positions 434 and 435 (27, 32). In contrast, an internal binding motif containing lysines at positions 252 and 255 in the closely related α-enolase of Streptococcus pneumoniae has been shown to play a pivotal role in the acquisition of plasminogen in this bacterial species (33). The octameric pneumococcal α-enolase structure consists of a tetramer of dimers. Hence, potential binding sites could be buried in the interface between subunits. In fact, the crystal structure of S. pneumoniae α-enolase revealed that the two C-terminal lysine residues are significantly less exposed than the internal plasminogen-binding motif (34).In this study, we constructed an in silico model of GAS SEN, based on the pneumococcal octameric α-enolase crystal structure, and validated this model using ion mobility (IM) mass spectrometry (MS). Site-directed mutagenesis followed by structural and functional analyses revealed that Lys³⁴⁴ plays a crucial role in structural integrity and enzymatic function. Furthermore, we demonstrate that the plasminogen-binding motif residues Lys²⁵² and Lys²⁵⁵ and the C-terminal Lys⁴³⁴ and Lys⁴³⁵ residues are located adjacently in the GAS SEN structure and play a concerted role in the binding of human plasminogen.     

Identification and biochemical characterization of a eukaryotic-type serine/threonine kinase and its cognate phosphatase in Streptococcus pyogenes: their biological functions and substrate identification

A eukaryotic-type signaling system in group A Streptococcus (GAS) was identified and characterized. This system comprises primarily the products of two co-transcribed genes, a eukaryotic-type Ser/Thr kinase (SP-STK) and phosphatase (SP-STP) and their endogenous substrate histone-like protein (SP-HLP). Enzyme activities of SP-STK and SP-STP primarily depended on Mn(2+). The site on the substrate for reversible phosphorylation by these enzymes was found to be only the threonine residue. Using specific antibodies generated against these proteins, SP-STK was found to be membrane-associated with its N-terminal kinase domain facing the cytoplasm and its C-terminal repeat domain outside the membrane and cell-wall associated. Further, SP-STP, primarily a cytoplasmic protein, was found to be a major secretory protein of GAS and essential for bacterial survival. Three isogenic mutants, lacking either the entire SP-STK, or one of its two domains, were found displaying distinct pleiotropic effects on growth, colony morphology, cell division/septation, surface protein/virulence factor expression, bacterial ability to adhere to and invade human pharyngeal cells, and resist phagocytosis by human neutrophils. In addition to these properties, the ability of these three proteins to modulate the expression of the major virulence factors, the M protein and the capsule, indicates that these proteins are structurally and functionally distinct from the kinases and phosphatases described in other microorganisms and play a key role in GAS pathogenesis.