47 research outputs found
Synthesis and transfer of galactolipids in the chloroplast envelope membranes of \u3ci\u3eArabidopsis thaliana\u3c/i\u3e
Galactolipids [monogalactosyldiacylglycerol (MGDG) and digalactosyldiacylglycerol
(DGDG)] are the hallmark lipids of photosynthetic
membranes. The galactolipid synthases MGD1 and DGD1
catalyze consecutive galactosyltransfer reactions but localize to the
inner and outer chloroplast envelopes, respectively, necessitating
intermembrane lipid transfer. Here we show that the N-terminal
sequence of DGD1 (NDGD1) is required for galactolipid transfer
between the envelopes. Different diglycosyllipid synthases (DGD1,
DGD2, and Chloroflexus glucosyltransferase) were introduced into
the dgd1-1 mutant of Arabidopsis in fusion with N-terminal extensions
(NDGD1 and NDGD2) targeting to the outer envelope. Reconstruction
of DGDG synthesis in the outer envelope membrane was
observed only with diglycosyllipid synthase fusion proteins carrying
NDGD1, indicating that NDGD1 enables galactolipid translocation
between envelopes. NDGD1 binds to phosphatidic acid (PA) in membranes
and mediates PA-dependent membrane fusion in vitro.
These findings provide a mechanism for the sorting and selective
channeling of lipid precursors between the galactolipid pools of the
two envelope membranes
Implications of Below-Ground Allelopathic Interactions of Camelina sativa and Microorganisms for Phosphate Availability and Habitat Maintenance
Toxic breakdown products of young Camelina sativa (L.) Crantz, glucosinolates can eliminate microorganisms in the soil. Since microorganisms are essential for phosphate cycling, only insensitive microorganisms with phosphate-solubilizing activity can improve C. sativa’s phosphate supply. In this study, 33P-labeled phosphate, inductively coupled plasma mass spectrometry and pot experiments unveiled that not only Trichoderma viride and Pseudomonas laurentiana used as phosphate-solubilizing inoculants, but also intrinsic soil microorganisms, including Penicillium aurantiogriseum, and the assemblies of root-colonizing microorganisms solubilized as well phosphate from apatite, trigger off competitive behavior between the organisms. Driving factors in the competitiveness are plant and microbial secondary metabolites, while glucosinolates of Camelina and their breakdown products are regarded as key compounds that inhibit the pathogen P. aurantiogriseum, but also seem to impede root colonization of T. viride. On the other hand, fungal diketopiperazine combined with glucosinolates is fatal to Camelina. The results may contribute to explain the contradictory effects of phosphate-solubilizing microorganisms when used as biofertilizers. Further studies will elucidate impacts of released secondary metabolites on coexisting microorganisms and plants under different environmental conditions
Marine Myxobacteria as a Source of Antibiotics—Comparison of Physiology, Polyketide-Type Genes and Antibiotic Production of Three New Isolates of Enhygromyxa salina
Three myxobacterial strains, designated SWB004, SWB005 and SWB006, were obtained from beach sand samples from the Pacific Ocean and the North Sea. The strains were cultivated in salt water containing media and subjected to studies to determine their taxonomic status, the presence of genes for the biosynthesis of polyketides and antibiotic production. 16S rDNA sequence analysis revealed the type strain Enhygromyxa salina SHK-1T as their closest homolog, displaying between 98% (SWB005) and 99% (SWB004 and SWB006) sequence similarity. All isolates were rod-shaped cells showing gliding motility and fruiting body formation as is known for myxobacteria. They required NaCl for growth, with an optimum concentration of around 2% [w/v]. The G + C-content of genomic DNA ranged from 63.0 to 67.3 mol%. Further, the strains were analyzed for their potential to produce polyketide-type structures. PCR amplified ketosynthase-like gene fragments from all three isolates enhances the assumption that these bacteria produce polyketides. SWB005 was shown to produce metabolites with prominent antibacterial activity, including activity towards methicillin resistant Staphylococcus aureus (MRSA) and Staphylococcus epidermidis (MRSE)
Ablation of glucosinolate accumulation in the oil crop Camelina sativa by targeted mutagenesis of genes encoding the transporters GTR1 and GTR2 and regulators of biosynthesis MYB28 and MYB29
Camelina sativa is an oil crop with low input costs and resistance to abiotic and biotic stresses. The presence of glucosinolates, plant metabolites with adverse health effects, restricts the use of camelina for human and animal nutrition. Cas9 endonuclease-based targeted mutagenesis of the three homeologs of each of the glucosinolate transporters CsGTR1 and CsGTR2 caused a strong decrease in glucosinolate amounts, highlighting the power of this approach for inactivating multiple genes in a hexaploid crop. Mutagenesis of the three homeologs each encoding the transcription factors CsMYB28 and CsMYB29 resulted in the complete loss of glucosinolates, representing the first glucosinolate-free Brassicaceae crop. The oil and protein contents and the fatty acid composition of the csgtr1csgtr2 and csmyb28csmyb29 mutant seeds were not affected. The decrease and elimination of glucosinolates improves the quality of the oil and press cake of camelina, which thus complies with international standards regulating glucosinolate levels for human consumption and animal feeding
Two Distinct Cardiolipin Synthases Operate in Agrobacterium tumefaciens.
Cardiolipin (CL) is a universal component of energy generating membranes. In most bacteria, it is synthesized via the condensation of two molecules phosphatidylglycerol (PG) by phospholipase D-type cardiolipin synthases (PLD-type Cls). In the plant pathogen and natural genetic engineer Agrobacterium tumefaciens CL comprises up to 15% of all phospholipids in late stationary growth phase. A. tumefaciens harbors two genes, atu1630 (cls1) and atu2486 (cls2), coding for PLD-type Cls. Heterologous expression of either cls1 or cls2 in Escherichia coli resulted in accumulation of CL supporting involvement of their products in CL synthesis. Expression of cls1 and cls2 in A. tumefaciens is constitutive and irrespective of the growth phase. Membrane lipid profiling of A. tumefaciens mutants suggested that Cls2 is required for CL synthesis at early exponential growth whereas both Cls equally contribute to CL production at later growth stages. Contrary to many bacteria, which suffer from CL depletion, A. tumefaciens tolerates large changes in CL content since the CL-deficient cls1/cls2 double mutant showed no apparent defects in growth, stress tolerance, motility, biofilm formation, UV-stress and tumor formation on plants
Glycoengineering of Cyanobacterial Thylakoid Membranes for Future Studies on the Role of Glycolipids in Photosynthesis
Two distinct cardiolipin synthases operate in
Cardiolipin (CL) is a universal component of energy generating membranes. In most bacteria, it is synthesized via the condensation of two molecules phosphatidylglycerol (PG) by phospholipase D-type cardiolipin synthases (PLD-type Cls). In the plant pathogen and natural genetic engineer CL comprises up to 15% of all phospholipids in late stationary growth phase. harbors two genes, () and (), coding for PLD-type Cls. Heterologous expression of either or in resulted in accumulation of CL supporting involvement of their products in CL synthesis. Expression of and in is constitutive and irrespective of the growth phase. Membrane lipid profiling of mutants suggested that Cls2 is required for CL synthesis at early exponential growth whereas both Cls equally contribute to CL production at later growth stages. Contrary to many bacteria, which suffer from CL depletion, tolerates large changes in CL content since the CL-deficient double mutant showed no apparent defects in growth, stress tolerance, motility, biofilm formation, UV-stress and tumor formation on plants
A Processive Glycosyltransferase Involved in Glycolipid Synthesis during Phosphate Deprivation in Mesorhizobium lotiâ–¿ â€
Natural habitats are often characterized by a low availability of phosphate. In plants and many bacteria, phosphate deficiency causes different physiological responses, including the replacement of phosphoglycerolipids in the membranes with nonphosphorous lipids. We describe here a processive glycosyltransferase (Pgt) in Mesorhizobium loti (Rhizobiales) involved in the synthesis of di- and triglycosyldiacylglycerols (DGlycD and TGlycD) during phosphate deprivation. Cells of the corresponding Δpgt deletion mutant are deficient in DGlycD and TGlycD. Additional Pgt-independent lipids accumulate in Mesorhizobium after phosphate starvation, including diacylglyceryl trimethylhomoserine (DGTS) and ornithine lipid (OL). The accumulation of the nonphosphorous lipids during phosphate deprivation leads to the reduction of phosphoglycerolipids from 90 to 50%. Nodulation experiments of Mesorhizobium wild type and the Δpgt mutant with its host plant, Lotus japonicus, revealed that DGlycD and TGlycD are not essential for nodulation under phosphate-replete or -deficient conditions. Lipid measurements showed that the Pgt-independent lipids including OL and DGTS accumulate to higher proportions in the Δpgt mutant and therefore might functionally replace DGlycD and TGlycD during phosphate deprivation
Synthesis and transfer of galactolipids in the chloroplast envelope membranes of \u3ci\u3eArabidopsis thaliana\u3c/i\u3e
Galactolipids [monogalactosyldiacylglycerol (MGDG) and digalactosyldiacylglycerol
(DGDG)] are the hallmark lipids of photosynthetic
membranes. The galactolipid synthases MGD1 and DGD1
catalyze consecutive galactosyltransfer reactions but localize to the
inner and outer chloroplast envelopes, respectively, necessitating
intermembrane lipid transfer. Here we show that the N-terminal
sequence of DGD1 (NDGD1) is required for galactolipid transfer
between the envelopes. Different diglycosyllipid synthases (DGD1,
DGD2, and Chloroflexus glucosyltransferase) were introduced into
the dgd1-1 mutant of Arabidopsis in fusion with N-terminal extensions
(NDGD1 and NDGD2) targeting to the outer envelope. Reconstruction
of DGDG synthesis in the outer envelope membrane was
observed only with diglycosyllipid synthase fusion proteins carrying
NDGD1, indicating that NDGD1 enables galactolipid translocation
between envelopes. NDGD1 binds to phosphatidic acid (PA) in membranes
and mediates PA-dependent membrane fusion in vitro.
These findings provide a mechanism for the sorting and selective
channeling of lipid precursors between the galactolipid pools of the
two envelope membranes