Alterations in Nitric Oxide Activity and Sensitivity in Early Streptozotocin-Induced Diabetes Depend on Arteriolar Size

Changes in NO activity may play an important role in the early increase in microvascular flow that has been implicated in the pathogenesis of diabetic microangiopathy. We assessed, in the in situ spinotrapezius muscle preparation of 6 weeks'' streptozotocin-diabetic rats (n = 6) and of agematched controls (n = 8), basal inside diameters of A2–A4 arterioles and the reactivity to topically applied acetylcholine and nitroprusside, before and after N^G-nitro-L-arginine. In diabetic rats, cholinergic vasodilatation in A2–A4 arterioles was intact. Basal diameter in A3 and A4 arterioles was significantly higher in streptozotocin-diabetic rats. The increased basal diameter in A3 arterioles was partially due to an increased contribution of NO to basal diameter. The response to nitroprusside was impaired in streptozotocin-diabetic rats in A2, but not in A3 and A4 arterioles. Thus, this study shows that NO activity and sensitivity are altered after 6 weeks of streptozotocin-induced diabetes. These streptozotocin-induced changes are anatomically specific and, for arterioles, depend on their position within the vascular tree.     

Induction of indole synthesis in the appendix of Sauromatum guttatum Schott

Induction of indole synthesis in young appendix sections ofSauromatum guttatum Schott was studied. The inducer, known ascalorigen, a compound synthesized in the mature staminate flowerbuds, is capable of triggering a rapid metabolic spurt in theappendix of the inflorescence. The induced indole-formationlasts for only a short period of time, and is similar to thenormal pattern of indole synthesis. Under the experimental conditions,indole was detectable after 7 to 8 hr of calorigen treatmentbut had disappeared about 35 hr later. The moment when indoleis present in maximal amount coincides with that of maximalheat production, i.e., about 27 hr after the application ofcalorigen. A simple and sensitive bioassay for detection ofcalorigen, based on the formation of indole, could be devised. Calorigen also causes, to a lesser extent, a temperature-riseof those young floral parts (male, female and sterile tissues)where indole is not detectable at any time. The time sequenceof the induced production of heat for the various floral partsmimics that of a natural metabolic flare-up. Extracts prepared from the mature staminate flowers of Arummaculatum L., Arum dioscoridis Sibth and Sm., and Dracunculusvulgaris Schott were all able to induce the formation of indolein the appendix of Sauromatum in a fashion similar to that causedby the staminate flower extract of this plant. (Received February 12, 1972; )     

Resurrecting complexity: the interplay of plasticity and rapid evolution in the multiple trait response to strong changes in predation pressure in the water flea Daphnia magna

A resurrection ecology reconstruction of 14 morphological, life history and behavioural traits revealed that a natural Daphnia magna population rapidly tracked changes in fish predation by integrating phenotypic plasticity and widespread evolutionary changes both in mean trait values and in trait plasticity. Increased fish predation mainly generated rapid adaptive evolution of plasticity (especially in the presence of maladaptive ancestral plasticity) resulting in an important change in the magnitude and direction of the multivariate reaction norm. Subsequent relaxation of the fish predation pressure resulted in reversed phenotypic plasticity and mainly caused evolution of the trait means towards the ancestral pre‐fish means. Relaxation from fish predation did, however, not result in a complete reversal to the ancestral fishless multivariate phenotype. Our study emphasises that the study population rapidly tracked environmental changes through a mosaic of plasticity, evolution of trait means and evolution of plasticity to generate integrated phenotypic changes in multiple traits.     

Sexual reproduction in the arum lily family,with emphasis on thermogenicity

Summary Floral thermogenicity, which is found in several representatives of half a dozen angiosperm families, is most pronounced in the Araceae. It is based on the operation of an alternative, cyanide-resistant electron transport chain which, in contrast to the classic cytochrome oxidase system, produces little ATP; most of the energy originally locked up in the respiratory substrate usually starch — is therefore liberated in the form of heat. The biological function of this (biochemically wasteful) system is to release the heat to serve as a volatilizer for the floral odors (often containing aliphatic amines, indole and skatole) that attract the insect pollinators. This makes the survival value of thermogenesis (for the plant species) immediately clear. Thermogenicity is under tight biological control, as demonstrated by the fact that the same ceiling temperature is always reached, regardless of ambient temperature. In Eastern skunk cabbage (Symplocarpus foetidus), which flowers very early in spring, that ceiling is about 20° C, in tropical forms such as Xanthosoma robustum and Philodendron selloum, it lies in the 42°–44° C range. In several instances, e.g., in Arum and in Sauromatum, the voodoo lily, thermogenicity manifests itself as a flare-up of only a few hours' duration, a respiratory explosion that can lead to rates of metabolism that compare favorably with those of a hovering hummingbird. The metabolic peak is always reached at a particular time of day, which is different for the different arum lily species, and thus reduces competition for pollinators. The odors that accompany the heat are also very characteristic, appealing to different pollinator classes and further reducing such competition. In the voodoo lily and in Arum, the primary site for the production of both heat and odor is the naked appendix of the inflorescence, which acts as a specialized osmophore or odor carrier. The first explosion may be followed by another one several hours later, which manifests itself in the floral chamber of the inflorescence and is under strict photoperiodic control. In Sauromatum, the first metabolic explosion is triggered by a plant hormone, originally referred to as calorigen, which originates in the primordia of the staminate flowers and moves from there into the appendix where it exerts its action after a lag-time of about a day — an indication that synthesis of new enzymatic protein (through unblocking of certain genes?) may well be involved. In 1987, calorigen was shown to be identical with salicylic acid. This compound was already known to induce flowering in certain duck-weeds, Lemnaceae, which until recently were regarded as belonging to the same family as arum lilies. In certain water lilies (Nymphaeaceae), thermogenicity is combined with a pollination syndrome very similar to that of Arum and Sauromatum but involving temporary trap flowers.Dedicated to the memory of A.W.H. van Herk, pioneer in the study of arum lilies, superb lecturer, and unselfish human being     

A 4-base-pair deletion polymorphism in man

Partial nucleotide sequencing of C11p11, a probe mapping close to the gene determining familial adenomatous polyposis (FAP) on human chromosome 5, in 4 unrelated persons has revealed a 4-base-pair deletion variant designated DELI at an arbitrary DNA locus D5S71. For screening the deletion variants that may frequently occur in the non-coding DNA sequences, we set up a non-invasive procedure which involves DNA amplification by PCR, simple polyacrylamide gel electrophoresis and direct visualisation of alleles under long wave ultraviolet light by ethidium bromide staining.     

Bioanalysis of aplidine, a new marine antitumoral depsipeptide, in plasma by high-performance liquid chromatography after derivatization with trans-4′-hydrazino-2-stilbazole

A sensitive bio-analytical assay in plasma of the depsipeptide aplidine is reported, based on reversed-phase liquid chromatography and fluorescence detection of the trans-4′-hydrazino-2-stilbazole (4′H2S) derivative of the analyte. At ambient temperature, two conformations of the depsipeptide are observed in solution due to cis–trans isomerism at the proline–pyruvoyl peptide bond. Aplidine is isolated from the matrix by solid-phase extraction on an octadecyl modified silica stationary phase. After evaporation of the acetone eluate, a derivatization with 4′H2S is performed in a water–acetonitrile mixture at pH 4. The reaction mixture is injected directly into the chromatograph and the analyte is quantified by fluorescence detection at 410 and 560 nm for excitation and emission, respectively. The method has been validated in the 2–100 ng/ml-range, 2 ng/ml being the lower limit of quantification. Precision and accuracy both meet the current requirements for a bioanalytical assay. The identity of the 4′H2S reaction products of aplidine have been confirmed by mass spectrometric analysis. Finally, the method has been employed for a pilot pharmacokinetic study of aplidine in mice which demonstrated its usefulness for pharmacological research.     

Temperature-driven proliferation of Tetracapsuloides bryosalmonae in bryozoan hosts portends salmonid declines

Proliferative kidney disease (PKD) is an emerging disease of salmonid fishes. It is provoked by temperature and caused by infective spores of the myxozoan parasite Tetracapsuloides bryosalmonae, which develops in freshwater bryozoans. We investigated the link between PKD and temperature by determining whether temperature influences the proliferation of T. bryosalmonae in the bryozoan host Fredericella sultana. Herein we show that increased temperatures drive the proliferation of T. bryosalmonae in bryozoans by provoking, accelerating and prolonging the production of infective spores from cryptic stages. Based on these results we predict that PKD outbreaks will increase further in magnitude and severity in wild and farmed salmonids as a result of climate-driven enhanced proliferation in invertebrate hosts, and urge for early implementation of management strategies to reduce future salmonid declines.     

Streptococcus mutans Competence-Stimulating Peptide Inhibits Candida albicans Hypha Formation

The oral cavity is colonized by microorganisms growing in biofilms in which interspecies interactions take place. Streptococcus mutans grows in biofilms on enamel surfaces and is considered one of the main etiological agents of human dental caries. Candida albicans is also commonly found in the human oral cavity, where it interacts with S. mutans. C. albicans is a polymorphic fungus, and the yeast-to-hypha transition is involved in virulence and biofilm formation. The aim of this study was to investigate interkingdom communication between C. albicans and S. mutans based on the production of secreted molecules. S. mutans UA159 inhibited C. albicans germ tube (GT) formation in cocultures even when physically separated from C. albicans. Only S. mutans spent medium collected in the early exponential phase (4-h-old cultures) inhibited the GT formation of C. albicans. During this phase, S. mutans UA159 produces a quorum-sensing molecule, competence-stimulating peptide (CSP). The role of CSP in inhibiting GT formation was confirmed by using synthetic CSP and a comC deletion strain of S. mutans UA159, which lacks the ability to produce CSP. Other S. mutans strains and other Streptococcus spp. also inhibited GT formation but to different extents, possibly reflecting differences in CSP amino acid sequences among Streptococcus spp. or differences in CSP accumulation in the media. In conclusion, CSP, an S. mutans quorum-sensing molecule secreted during the early stages of growth, inhibits the C. albicans morphological switch.The oral cavity is colonized by many different microbial species, where most reside in biofilms. Because of its multispecies nature, the oral microbial community is one of the best biofilm models for studying interspecies interactions (17). The gram-positive bacterium Streptococcus mutans shows a high prevalence in dental biofilms, and it is considered to be the major etiological agent involved in human dental caries (21). The fungal species Candida albicans constitutes a minor part of the total microbial flora (19) and can be isolated as a commensal from the oral cavity of 50% to 60% of healthy adults (33). However, in immunocompromised individuals (for example, due to human immunodeficiency virus infection or as a result of chemotherapy) and elderly patients, this fungus often leads to candidiasis (24). C. albicans is a polymorphic fungus that can exist in three morphotypes: budding yeast, pseudohypha, and true hypha (5). The morphological switch from yeast to hyphal cells is important in many processes, such as virulence (22) and biofilm formation (10, 18), and is therefore the subject of many studies.Bacteria and yeasts are often found together in vivo, and there is growing evidence that interspecies, and even interkingdom, interactions occur within these populations (7). These interactions can be mediated through signaling molecules (40), as recently described for the interaction between C. albicans and Pseudomonas aeruginosa, an opportunistic bacterial pathogen (15). N-3-oxo-C₁₂ homoserine lactone (HSL), a signaling molecule involved in bacterial quorum sensing, completely represses C. albicans hypha formation without altering the growth rate. Although many gram-negative bacteria produce HSLs with shorter acyl chains (e.g., C₄-HSL), the inhibition of C. albicans hypha formation is caused specifically by long-chained HSL molecules. In addition, related, non-HSL molecules with long acyl chains, such as dodecanol and farnesol, also inhibit the hypha formation of C. albicans (8).A recent report described the coculturing of C. albicans and S. mutans in model oral biofilms on hydroxyapatite (26). It was shown that S. mutans increased the growth of C. albicans by stimulating coadhesion while simultaneously suppressing the formation of hyphae. S. mutans is a gram-positive bacterium and does not produce HSL-type molecules, and the nature of the interaction with C. albicans is presently unknown. In this study, the interaction between S. mutans and C. albicans was investigated by studying the effect of secreted molecules of S. mutans on C. albicans hypha formation.