Fruit structure and systematics of Monimiaceae s.s. (Laurales)

Fruit structure (anatomy) was studied in 27 species of 15 genera of Monimiaceae s.s. Almost all have apocarpous gynoecia, with the carpels more or less surrounded by a floral cup. The fruitlets are presented on the opened floral cup, which, depending on its pre‐ and post‐floral development, differentially contributes to the attractive part of the mature fruit. Morphologically similar fruits may differ conspicuously in anatomical structure. Based on anatomical characters two different fruit forms were found: drupe(let)s (with compact sclerenchymatic endocarp forming a stone: putamen) and berry(let)s (with parenchymatic endocarp, and mesocarp parenchyma containing isolated sclereid nests). Four types of drupelets differing by the endocarp structure were tentatively distinguished: (1) the Monimia‐type has a many‐cell‐layered putamen of large isodiametric sclereids, interrupted on the ventral side by few radial rows of small sclereids; (2) the Hortonia‐type has a few‐cell‐layered putamen of isodiametric, especially thick‐walled sclereids – it may be composed of two lateral halves, i.e. with the sclerenchyma partially interrupted on the ventral and dorsal sides (but without rows of small sclereids); (3) the Mollinedia‐type has a few‐cell‐layered putamen, with more or less radially elongate sclereids with wavy cell walls; and (4) the Hedycarya‐type has a one‐cell‐layered putamen of pronouncedly radially elongate sclereids with wavy cell walls. Drupelets of some taxa with a single‐cell‐layered endocarp with only weakly thickened cell walls may represent a transition from drupelets to berrylets. The fruit structure supports three major clades recognized earlier by morphological studies and by molecular phylogenetic analyses: (1) Monimioideae (Monimia‐type drupelets), (2) Hortonieae of Mollinedioideae (Hortonia‐type drupelets), and (3) the remainder of Mollinedioideae (Hedycarya‐ and Mollinedia‐types) and berrylets. Fruit structure also supports the close relationship of Monimiaceae and Lauraceae. © 2007 The Linnean Society of London, Botanical Journal of the Linnean Society, 2007, 153 , 265–285.     

Recognition of Neurohormones of the NPY Family by Their Receptors

In this review a structural approach developed to answer the question whether hormones from the neuropeptide Y (NPY) family are recognized directly from solution or from the membrane-bound state is described. The chosen strategy is built onto a comparison of a set of peptides with well-known pharmacology and investigates whether similarities of structures of pharmacologically related peptides are higher in solution or in the membrane-bound state. Moreover, we have established the membrane-association mode of these peptides and contributed to our understanding of the structural features of these hormones both when placed in bulk solution and when bound to membranes. As a result we propose a receptor recognition pathway that includes initial association with the membrane and requires the peptides to come off the membrane to diffuse into the binding pocket of the receptor. This review also presents methodology recently developed by us to simulate the structural transition the peptides undergo when diffusing from bulk solution onto the membrane.     

A Molecular Perspective on Ecological Differentiation and Biogeography of Cyclotrichiid Ciliates

ABSTRACT. Cyclotrichiids are of ecological and evolutionary interest by virtue of their importance in red tide formation, their highly divergent small subunit (SSU) ribosomal RNA (rRNA) genes, kleptoplastidy, and utility as indicators of eutrophication. However, only seven strains have had their SSU rRNA genes sequenced and their environmental diversity and distribution are largely unknown. We probed 67 globally dispersed freshwater column/sediment and soil DNA samples (eDNAs) and constructed 24 environmental gene libraries using polymerase chain reaction primers specific to an uncharacterised cyclotrichiid subgroup. We reveal a novel, globally ubiquitous freshwater clade comprising 25 genetically distinct SSU ribosomal DNA (rDNA) sequences (SSU-types). Some identical SSU-types were detected at globally widely distributed sites. The SSU-types form four distinct phylogenetic clusters according to marine or non-marine provenance, suggesting at least one major marine–freshwater evolutionary transition within the cyclotrichiids. We used the same primers to sample intensively 18 sampling points in 13 closely situated lakes, each characterised by 14 environmental variables, and showed that molecular detection or non-detection of cyclotrichiids was most significantly influenced by levels of total phosphorus, dissolved organic carbon, and chlorophyll a . Within the subset of lakes in which cyclotrichiids were detected, closely related SSU-types differed in their ecological preferences to pH, total phosphorus, and sample depth.