Growth differentiation factor 15 (GDF15) and semaglutide inhibit food intake and body weight through largely distinct, additive mechanisms.

AIMS: To evaluate whether the potent hypophagic and weight-suppressive effects of growth differentiation factor-15 (GDF15) and semaglutide combined would be a more efficacious antiobesity treatment than either treatment alone by examining whether the neural and behavioural mechanisms contributing to their anorectic effects were common or disparate. MATERIALS/METHODS: Three mechanisms were investigated to determine how GDF15 and semaglutide induce anorexia: the potentiation of the intake suppression by gastrointestinal satiation signals; the reduction in motivation to feed; and the induction of visceral malaise. We then compared the effects of short-term, combined GDF15 and semaglutide treatment on weight loss to the individual treatments. Rat pharmaco-behavioural experiments assessed whether GDF15 or semaglutide added to the satiating effects of orally gavaged food and exogenous cholecystokinin (CCK). A progressive ratio operant paradigm was used to examine whether GDF15 or semaglutide reduced feeding motivation. Pica behaviour (ie, kaolin intake) and conditioned affective food aversion testing were used to evaluate visceral malaise. Additionally, fibre photometry studies were conducted in agouti-related protein (AgRP)-Cre mice to examine whether GDF15 or semaglutide, alone or in combination with CCK, modulate calcium signalling in hypothalamic AgRP neurons. RESULTS: Semaglutide reduced food intake by amplifying the feeding-inhibitory effect of CCK or ingested food, inhibited the activity of AgRP neurons when combined with CCK, reduced feeding motivation and induced malaise. GDF15 induced visceral malaise but, strikingly, did not affect feeding motivation, the satiating effect of ingested food or CCK signal processing. Combined GDF15 and semaglutide treatment produced greater food intake and body weight suppression than did either treatment alone, without enhancing malaise. CONCLUSIONS: GDF15 and semaglutide reduce food intake and body weight through largely distinct processes that produce greater weight loss and feeding suppression when combined.

Pancreatogastrostomy Versus Pancreatojejunostomy for RECOnstruction After PANCreatoduodenectomy (RECOPANC, DRKS 00000767): Perioperative and Long-term Results of a Multicenter Randomized Controlled Trial.

OBJECTIVES: To assess pancreatic fistula rate and secondary endpoints after pancreatogastrostomy (PG) versus pancreatojejunostomy (PJ) for reconstruction in pancreatoduodenectomy in the setting of a multicenter randomized controlled trial. BACKGROUND: PJ and PG are established methods for reconstruction in pancreatoduodenectomy. Recent prospective trials suggest superiority of the PG regarding perioperative complications. METHODS: A multicenter prospective randomized controlled trial comparing PG with PJ was conducted involving 14 German high-volume academic centers for pancreatic surgery. The primary endpoint was clinically relevant postoperative pancreatic fistula. Secondary endpoints comprised perioperative outcome and pancreatic function and quality of life measured at 6 and 12 months of follow-up. RESULTS: From May 2011 to December 2012, 440 patients were randomized, and 320 were included in the intention-to-treat analysis. There was no significant difference in the rate of grade B/C fistula after PG versus PJ (20% vs 22%, P = 0.617). The overall incidence of grade B/C fistula was 21%, and the in-hospital mortality was 6%. Multivariate analysis of the primary endpoint disclosed soft pancreatic texture (odds ratio: 2.1, P = 0.016) as the only independent risk factor. Compared with PJ, PG was associated with an increased rate of grade A/B bleeding events, perioperative stroke, less enzyme supplementation at 6 months, and improved results in some quality of life parameters. CONCLUSIONS: The rate of grade B/C fistula after PG versus PJ was not different. There were more postoperative bleeding events with PG. Perioperative morbidity and mortality of pancreatoduodenectomy seem to be underestimated, even in the high-volume center setting.

Nonribosomal peptide synthetase genes occur in most cyanobacterial genera as evidenced by their distribution in axenic strains of the PCC.

Previous studies largely carried out with environmental samples or axenic and non-axenic cultures suggested that cyanobacteria may be a rich source of hitherto unexplored bioactive compounds. This has been confirmed in the present study by a screening of 146 axenic strains from the Pasteur Culture Collection (PCC) of cyanobacteria. Use of degenerate PCR primers, designed on the basis of conserved sequence motifs in the aminoacyl-adenylation domain of peptide synthetases, revealed the presence of the corresponding genes in the majority (75.3%) of the strains examined. Among unicellular cyanobacteria, only Chamaesiphon sp. strain PCC 6605, two strains of Gloeocapsa and most Microcystis isolates (22 out of 24) contained these genes; no amplicons were detected for any members of the genera Cyanothece, Gloeobacter and Gloeothece and the genetically diverse representatives of Synechococcus and Synechocystis. By contrast, eight out of ten pleurocapsalean members, 16 out of 25 oscillatorian strains, and all but two of the 63 filamentous heterocystous cyanobacteria tested gave positive amplification results. This information will be highly valuable for further exploring the corresponding cyanobacterial peptides and for elucidating the bioactivity of such non-ribosomally synthesized molecules.

Altered expression of two light-dependent genes in a microcystin-lacking mutant of Microcystis aeruginosa PCC 7806.

Microcystin is a potent inhibitor of eukaryotic protein phosphatases and has been implicated in causing hepatotoxicity to humans and animals worldwide. It is produced primarily by the bloom-forming cyanobacterium Microcystis aeruginosa, although the function of the peptide in this micro-organism is unknown. In this study, a microcystin-related protein, MrpA, was identified using a microcystin-lacking mutant of M. aeruginosa, PCC 7806. Comparative two-dimensional protein electrophoresis showed that MrpA was strongly expressed in wild-type PCC 7806, but was not detectable in the mcyB mutant. MrpA showed similarity to the RhiA protein from Rhizobium leguminosarum, which is encoded by the rhiABC operon and controlled by quorum-sensing mediators. Sequencing of mrpA flanking regions in M. aeruginosa PCC 7806 revealed the presence of a rhiB homologue, mrpB, directly downstream of mrpA. Northern blot analyses of mrpA expression in cells exposed to different light conditions revealed a rapid decline of transcription under high light conditions. Most striking was a strong increase in transcript levels from cultures irradiated with blue light. The mrpA transcription level was strongly reduced in two independent microcystin-lacking mutants under all light conditions investigated.

Effects of cell-bound microcystins on survival and feeding of Daphnia spp.

The influence of cell-bound microcystins on the survival time and feeding rates of six Daphnia clones belonging to five common species was studied. To do this, the effects of the microcystin-producing Microcystis strain PCC7806 and its mutant, which has been genetically engineered to knock out microcystin synthesis, were compared. Additionally, the relationship between microcystin ingestion rate by the Daphnia clones and Daphnia survival time was analyzed. Microcystins ingested with Microcystis cells were poisonous to all Daphnia clones tested. The median survival time of the animals was closely correlated to their microcystin ingestion rate. It was therefore suggested that differences in survival among Daphnia clones were due to variations in microcystin intake rather than due to differences in susceptibility to the toxins. The correlation between median survival time and microcystin ingestion rate could be described by a reciprocal power function. Feeding experiments showed that, independent of the occurrence of microcystins, cells of wild-type PCC7806 and its mutant are able to inhibit the feeding activity of Daphnia. Both variants of PCC7806 were thus ingested at low rates. In summary, our findings strongly suggest that (i) sensitivity to the toxic effect of cell-bound microcystins is typical for Daphnia spp., (ii) Daphnia spp. and clones may have a comparable sensitivity to microcystins ingested with food particles, (iii) Daphnia spp. may be unable to distinguish between microcystin-producing and -lacking cells, and (iv) the strength of the toxic effect can be predicted from the microcystin ingestion rate of the animals.

Phosphorylation of proteins in the light-dependent signalling pathway of a filamentous cyanobacterium.

The genome of the filamentous cyanobacterium Calothrix sp. PCC7601 contains two genes, cphA and cphB, encoding proteins with similarity to plant phytochromes and bacterial histidine kinases. In vitro, CphA and CphB readily attach a tetrapyrrole chromophore to develop spectrally active holoproteins that are photointerconvertible between a red light-absorbing and a far-red light-absorbing form. Together with the putative response regulators, RcpA and RcpB, the putative histidine kinases, CphA and CphB, are suggested to constitute two two-component systems of light-dependent signal transduction. In this report, we demonstrate the kinase activity of both CphA and CphB. In vitro experiments carried out on the purified proteins show that CphA and CphB are autophosphorylated in the presence of ATP and that phospho-CphA is capable of efficient phosphotransfer to RcpA as is phospho-CphB towards RcpB. The autophosphorylation and the phosphorelay are dependent on light. Both activities are reduced under red light vs. far-red light irradiation. No phosphoryl transfer occurred between phospho-CphA and RcpB or between phospho-CphB and RcpA. The response regulators RcpA and RcpB can receive a phosphoryl moiety also from the small phospho-donor acetyl phosphate. The stability of the phosphorylated regulators is not affected by CphA and CphB or light.

Characterization of the cyanobacterial ycf37: mutation decreases the photosystem I content.

We have constructed and analysed a cyanobacterial mutant that lacks the putative homologue of ycf37, the chloroplast open reading frame 37, which is conserved in different algae, but missing in the plastome of higher plants. In this report we show that Ycf37 of Synechocystis sp. PCC 6803 contains three tetratrico-peptide repeat (TPR) units resembling the structural organization of Ycf3, a protein that has been suggested to function as a chaperone during photosystem (PS) I complex formation. We demonstrate a light-activated transcript accumulation of this gene. Inactivation of ycf37 leads to a lower PSI/PSII ratio and a higher phycocyanin/chlorophyll ratio in Synechocystis cells. The observed alterations in the ycf37 mutants and the structural organization of the gene product suggest a functional role in PSI stability or assembly.

Characterization of the Cph1 holo-phytochrome from Synechocystis sp. PCC 6803.

The cph1 gene from the unicellular cyanobacterium Synechoycstis sp. PCC 6803 encodes a protein with the characteristics of plant phytochromes and histidine kinases of two-component phospho-relay systems. Spectral and biochemical properties of Cph1 have been intensely studied in vitro using protein from recombinant systems, but virtually nothing is known about the situation in the natural host. In the present study, His6-tagged Cph1 was isolated from Synechocystis cells. The cph1-his gene was expressed either under the control of the natural cph1 promoter or over-expressed using the strong promoter of the psbA2 gene. Upon purification with nickel affinity chromatography, the presence of Cph1 in extracts was confirmed by immunoblotting and Zn2+-induced fluorescence. The Cph1 extracts exhibited a red/far-red photoactivity characteristic of phytochromes. Difference spectra were identical with those of the phycocyanobilin adduct of recombinant Cph1, implying that phycocyanobilin is the chromophore of Cph1 in Synechocystis.

Molecular biology of peptide and polyketide biosynthesis in cyanobacteria.

Cyanobacteria produce numerous and structurally diverse secondary metabolites, in particular nonribosomal peptide and polyketide structures. Various bioactivities could be assigned to these compounds, and some may prove useful either for development into commercial drugs or as biochemical research tools. Microcystin, a worldwide common cyanobacterial hepatotoxin, was the first metabolite whose nonribosomal biosynthesis could be confirmed by knock-out mutagenesis. The microcystin synthetase complex consists of peptide synthetases, polyketide synthases, and hybrid enzymes, and reveals a number of novel enzymatic features, signifying the potential of cyanobacterial biosynthetic systems for combinatorial biochemistry. Recent studies have shown the presence of peptide synthetase genes and polyketide synthase genes within a number of cyanobacterial genomes. This knowledge may be very valuable for future screening projects aimed at the detection of new bioactive compounds.

Structural organization of microcystin biosynthesis in Microcystis aeruginosa PCC7806: an integrated peptide-polyketide synthetase system.

BACKGROUND: Blooms of toxic cyanobacteria (blue-green algae) have become increasingly common in the surface waters of the world. Of the known toxins produced by cyanobacteria, the microcystins are the most significant threat to human and animal health. These cyclic peptides are potent inhibitors of eukaryotic protein phosphatases type 1 and 2A. Synthesized nonribosomally, the microcystins contain a number of unusual amino acid residues including the beta-amino polyketide moiety Adda (3-amino-9-methoxy-2,6, 8-trimethyl-10-phenyl-4,6-decadienoic acid). We have characterized the microcystin biosynthetic gene cluster from Microcystis aeruginosa PCC7806. RESULTS: A cluster spanning 55 kb, composed of 10 bidirectionally transcribed open reading frames arranged in two putative operons (mcyA-C and mcyD-J), has been correlated with microcystin formation by gene disruption and mutant analysis. Of the 48 sequential catalytic reactions involved in microcystin synthesis, 45 have been assigned to catalytic domains within six large multienzyme synthases/synthetases (McyA-E, G), which incorporate the precursors phenylacetate, malonyl-CoA, S-adenosyl-L-methionine, glutamate, serine, alanine, leucine, D-methyl-isoaspartate, and arginine. The additional four monofunctional proteins are putatively involved in O-methylation (McyJ), epimerization (McyF), dehydration (McyI), and localization (McyH). The unusual polyketide amino acid Adda is formed by transamination of a polyketide precursor as enzyme-bound intermediate, and not released during the process. CONCLUSIONS: This report is the first complete description of the biosynthesis pathway of a complex cyanobacterial metabolite. The enzymatic organization of the microcystin assembly represents an integrated polyketide-peptide biosynthetic pathway with a number of unusual structural and enzymatic features. These include the integrated synthesis of a beta-amino-pentaketide precursor and the formation of beta- and gamma-carboxyl-peptide bonds, respectively. Other features of this complex system also observed in diverse related biosynthetic clusters are integrated C- and N-methyltransferases, an integrated aminotransferase, and an associated O-methyltransferase and a racemase acting on acidic amino acids.

Light and the transcriptional response of the microcystin biosynthesis gene cluster.

Microcystin, a hepatotoxin known to be the cause of animal and human deaths, is produced by the bloom-forming cyanobacterium Microcystis aeruginosa in freshwater bodies worldwide. The toxin is produced nonribosomally via a multifunctional enzyme complex, consisting of both peptide synthetase and polyketide synthase modules coded for by the mcy gene cluster. The recent identification of the mcy genes in the production of microcystin synthetase for the first time provides an avenue to study the regulation of microcystin production at a genetic level. In this study, M. aeruginosa PCC7806 was grown either under continuous light of various intensities or under low light with subsequent short-term exposure to different light intensities and qualities and various stress factors. RNase protection assays were employed to observe the level of mcyB and mcyD transcription under each condition. Both mcyB and mcyD transcript levels were increased under high light intensities and red light. Blue light and certain artificial stress factors (methylviologen and NaCl) led to reduced transcript amounts. There appeared to be two light thresholds, between dark and low light (16 micromol of photons m(-2) s(-1)), and medium (31 micromol of photons m(-2) s(-1)) and high light (68 micromol of photons m(-2) s(-1)), at which a significant increase in transcription occurred. Our findings show that the effect of light on microcystin synthetase production is due to light quality and is initiated at certain threshold intensities, which are not necessarily reflected by observed intracellular toxin bioactivity.

Phage T4-like intermediates of DNA replication and recombination in the mitochondria of the higher plant Chenopodium album (L.).

We have studied intermediates of the recombination and replication of chromosomal mitochondrial (mt) DNA prepared from suspension cultured cells of Chenopodium album (L.) by electron microscopy during the whole growth cycle. We identified several types of potential recombination and replication intermediates including rosette-like structures, as well as other branched and sigma-like molecules. The absolute and relative amounts of these structures changed dramatically during the growth cycle, indicating high dynamics in the structural organization of the mt genome. The rosette-like molecules had sizes of 2-5 genome units and were found to contain putative replication forks and 'Holliday'-junctions known from recombination intermediates. The high number of rosettes during the first days of culture, and their drastic reduction in the stationary growth stage, were found to be inversely related to changes in the quantity of linear molecules of 40-200 kb. This observation suggests that linear molecules participate in the formation of giant branched rosette-like structures. Most linear molecules were previously found to have at least one single-stranded end, which may allow recombinative invasion of other double-stranded molecules. Thus, recombination events may lead to the formation of more complex molecules and initiate replication similar to phage T4. We propose the coexistence of a recombination-dependent mode of replication with a presumably recombination-independent rolling-circle mode of replication in the mitochondria of C. album.

Endochitinase gene-based phylogenetic analysis of Trichoderma.

DNA sequences of the single-copy gene coding for the 42 kDa endochitinase enzyme (EC 3.2.1.14) were used for phylogenetic analysis in Trichoderma. A set of 12 primers was developed and the entire gene was sequenced for 16 strains, and nucleotide and deduced amino acid sequences were compared to data from GenBank for additional Trichoderma strains. Analysis of the sequences revealed parsimony informative variation from 2.4 to 43.6% depending on the part of the gene (exons/introns) and the taxonomic level considered. Results are discussed in comparison to previous data from ITS-1 and ITS-2 rDNA sequencing and suggest the 42 kDa endochitinase gene as a potential molecular marker for reconstructing phylogenetic relationships in the genus Trichoderma at species level.

One RNA polymerase serving two genomes.

The land plant Arabidopsis thaliana contains three closely related nuclear genes encoding phage-type RNA polymerases (RpoT;1, RpoT;2 and RpoT;3). The gene products of RpoT;1 and RpoT;3 have previously been shown to be imported into mitochondria and chloroplasts, respectively. Here we show that the transit peptide of RpoT;2 possesses dual targeting properties. Transient expression assays in tobacco protoplasts as well as stable transformation of Arabidopsis plants demonstrate efficient targeting of fusion peptides consisting of the N-terminus of RpoT;2 joined to green fluorescent protein to both organelles. Thus, RpoT;2 might be the first RNA polymerase shown to transcribe genes in two different genomes. RNA polymerase activity of recombinant RpoT;2 is uneffected by the inhibitor tagetin, qualifying the gene product of RpoT;2 as a phage-type polymerase.

Inter-organellar crosstalk in higher plants: impaired chloroplast development affects mitochondrial gene and transcript levels.

Co-ordination of gene expression between the three genomes present in plastids, mitochondria and nucleus is of crucial importance for plant cells. Previous studies revealed that in white leaves of the albostrians (Hordeum vulgare cv. Haisa) mutant, photosynthesis-related plastid and nuclear genes are expressed only at an extremely low level. The plastids of this mutant lack ribosomes, photosynthetic activity and have only rudimentary membrane systems. Here we report on the expression of mitochondrial genes in albostrians barley. Steady-state RNA levels of the mitochondrial genes encoding cytochrome oxidase or ATPase subunits, coxII, coxIII, atpA, atp6, atp9 and cob, were observed to be consistently elevated in the white leaves but not in roots. Investigation of mitochondrial DNA revealed an about three-fold enhanced mitochondrial gene copy number in white compared to green leaf cells, but no differential amplification of mitochondrial genes. Analysis of plants in which the white albostrians plastids were combined with a new nuclear background showed that the enhanced transcript levels were a consequence of the impaired plastids and not of the nuclear albostrians allele. Furthermore, plants bleached by the carotenoid biosynthesis inhibitor norflurazon also showed an enhanced mitochondrial transcript level. These findings allow the conclusion that lack of chloroplast activity in an otherwise fully differentiated leaf leads to an increase in mitochondrial gene copy number and an elevated level of mitochondrial transcripts. Our results indicate an influence of plastids on the genetic apparatus of mitochondria in leaves but not in roots.

A gene family encoding glutathione peroxidase homologues in Hordeum vulgare (barley).

We have isolated and characterised three barley cDNAs encoding glutathione peroxidase (GPX) homologues, designated HVGPH1, HVGPH2 and HVGPH3. HVGPH1 may represent a cytosolic form of GPX. The structure of the HVGPH2 N-terminal domain is typical for a plastid transit peptide. A potential peroxisomal targeting sequence occurs near the N-terminus of HVGPH3. Transcript levels of HVGPH1 and HVGPH2 were increased in leaves undergoing stress. In contrast, HVGPH3 mRNA accumulation showed a negative response to stress. Our data indicate that the barley genome bears a small gene family encoding GPX homologues differing in their function and cellular localisation.

Cloning and characterization of three cDNAs encoding chloroplast RNA-binding proteins from barley (Hordeum vulgare L.): differential regulation of expression by light and plastid development.

Three cDNAs encoding chloroplast RNA-binding proteins (RNBPs) were identified in a screen of barley albostrians mutant expression libraries, and their binding and expression characteristics were determined. Two of these proteins, designated cp31AHv and cp31BHv, are closely related to group II, whereas the third, cp33Hv, is more similar to group III of the nuclear-encoded chloroplast RNBPs of dicot plants. Analysis of RNA from sections of primary leaves by Northern hybridization showed that the expression of these genes correlates with the stage of leaf development. The steady state transcript levels of the two genes encoding cp31BHv and cp33Hv, but not of the gene for cp31AHv, were positively affected by light. Moreover, a plastid factor is required for activation of cp31AHv transcription as revealed by the low level of cp31AHv mRNA in white leaves of the albostrians mutant and of seedlings treated with Norflurazon. Therefore, we propose the existence of a light-independent plastid-derived signal chain that regulates the expression of cp31AHv.

Comparative analysis of splicing of the complete set of chloroplast group II introns in three higher plant mutants.

The barley mutant albostrians and the maize mutants crs1 and crs2 are defective in the splicing of various plastid group II introns. By analysing tRNA precursors and several mRNAs not previously examined, the investigation of in vivo splicing defects in these mutants has been completed. The albostrians mutation causes the loss of plastid ribosomes resulting secondarily in a disruption of splicing of all subgroup IIA introns in the chloroplast. Thus MatK, the only putative chloroplast intron-specific maturase of higher plants, might have evolved to function in splicing of multiple introns. We show that in the case of tRNA-Ala(UGC)the first step of splicing is affected, as suggested by the absence of lariat molecules. Thus the plastid-encoded splicing factor lacking in albostrians must participate in the formation of the catalytically active structure. In contrast, a mutation in the nuclear gene crs1 prevents splicing of only one intron but causes specific additional effects as precursor transcripts for tRNA-Ile(GAU), tRNA-Ala(UGC), tRNA-Lys(UUU)and tRNA-Val(UAC), but not tRNA-Gly(UCC), have significantly enhanced steady-state levels in this mutant. Our data provide evidence for a variety of splicing factors and pathways in the chloroplast, some encoded by nuclear and some by chloroplast genes, and possibly for a dual function of some of these factors.

Nonribosomal peptide synthesis and toxigenicity of cyanobacteria.

Nonribosomal peptide synthesis is achieved in prokaryotes and lower eukaryotes by the thiotemplate function of large, modular enzyme complexes known collectively as peptide synthetases. These and other multifunctional enzyme complexes, such as polyketide synthases, are of interest due to their use in unnatural-product or combinatorial biosynthesis (R. McDaniel, S. Ebert-Khosla, D. A. Hopwood, and C. Khosla, Science 262:1546-1557, 1993; T. Stachelhaus, A. Schneider, and M. A. Marahiel, Science 269:69-72, 1995). Most nonribosomal peptides from microorganisms are classified as secondary metabolites; that is, they rarely have a role in primary metabolism, growth, or reproduction but have evolved to somehow benefit the producing organisms. Cyanobacteria produce a myriad array of secondary metabolites, including alkaloids, polyketides, and nonribosomal peptides, some of which are potent toxins. This paper addresses the molecular genetic basis of nonribosomal peptide synthesis in diverse species of cyanobacteria. Amplification of peptide synthetase genes was achieved by use of degenerate primers directed to conserved functional motifs of these modular enzyme complexes. Specific detection of the gene cluster encoding the biosynthetic pathway of the cyanobacterial toxin microcystin was shown for both cultured and uncultured samples. Blot hybridizations, DNA amplifications, sequencing, and evolutionary analysis revealed a broad distribution of peptide synthetase gene orthologues in cyanobacteria. The results demonstrate a molecular approach to assessing preexpression microbial functional diversity in uncultured cyanobacteria. The nonribosomal peptide biosynthetic pathways detected may lead to the discovery and engineering of novel antibiotics, immunosuppressants, or antiviral agents.