MORE MOLLUSCAN NAME-CHANGES, GENERIC AND SPECIFIC

Volema, Bolten, type V. paradisiaca, Bolten, has priority overMelongena, Schumacher, but may be used independently. Mayena, gen. nov., proposed for Biplex australasia, Perry. Turricula, Schumacher, is the correct name for Surcula, H. &A. Adams. Gelagna, Schaufuss, is equal to and antedates Paralagena, Dall. Partulida, Schaufuss, should replace Spiralinella, Chaster. Campanile, Fischer, has for type the recent species Cerithiumleve, Quoy & Gaimard, which is here renamed Campanile symbolicum,sp. nov. Campanilopa, gen. nov., introduced for the fossil Cerithiumgiganteum. Lam. Pleurotomoides, Bronn, has priority over Lora, Gistel, and Clathurella,Carpenter, all proposed as alternatives for Defrancia, Millet,preoccupied. Gabrielona, gen. nov., proposed for Phasianella nepeanensis,Gatliff & Gabriel. Orbitestella, gen. nov., for Cyclostrema bastowi, Gatliff. Megathura, Pilsbry, should be used instead of Macrochasma, Dall. Mitromorpha, auctt., is not Mitromorpha, Carpenter, which wasbased on Daphnella (?) filosa, Carpenter. Antimitra, gen. nov., is proposed for Pleurotoma agrota, Reeve,with which A. Adams' Mitromorpha lirata is congeneric. Lovellona, gen. nov., type Conus atramentosus. Reeve. Apaturris, gen. nov., type Mitramorpha expeditionis, Oliver. Callanaitis, gen. nov., type Venus yatei, Gray, for Salacia,Jukes-Browne, preoccupied. Anopsia, Gistel, is available for Psyche, Rang, preoccupied,and has priority over Verrillopsyche, Cossmann, proposed forHalopsyche, Kieferstein, preoccupied, introduced as substitutefor Rang's name. Hydromyles, Gistel, should be used for Euribia, Rang, preoccupied,as it is older than Kieferstein's name Theceurybia, for thesame genus. (Received 13 April 1917;     

Genetic Diversity of the Wild Banana Musa acuminata Colla in Malaysia as Evidenced by AFLP

Musa acuminata Colla (Musaceae), the wild progenitor of thecultivated banana, is highly variable in Malaysia and presentsseveral unresolved nomenclatural problems. AFLP was employedto distinguish among three subspecies of Musa acuminata(subsp.truncata and subsp. malaccensis from peninsular Malaysia andsubsp. microcarpa from Borneo) and to examine whether subsp.truncata is a distinct taxon. Eight primer combinations revealedmolecular markers specific for each of the three taxa. UPGMAcluster analysis showed the three taxa were distinct. Subspeciesmalaccensis which is endemic in peninsular Malaysia and subsp.microcarpa which is endemic in Borneo were found to be moresimilar to each other in their DNA patterns than they are tosubsp. truncata, which is endemic to peninsular Malaysia. Sincesubsp. truncata is genetically separate from subsp. malaccensisand subsp.microcarpa , it cannot be regarded as synonymous witheither of these subspecies. This paper sheds light on the nomenclatureof the three subspecies of Musa acuminata. Copyright 2001 Annalsof Botany Company Musa acuminata Colla, truncata, malaccensis, microcarpa, Musaceae, wild banana, genetic diversity, AFLP, DNA fingerprinting     

Estimating the capacity for improvement in risk prediction with a marker

Consider a set of baseline predictors X to predict a binaryoutcome D and let Y be a novel marker or predictor. This paperis concerned with evaluating the performance of the augmentedrisk model P(D = 1|Y,X) compared with the baseline model P(D= 1|X). The diagnostic likelihood ratio, DLR_X(y), quantifiesthe change in risk obtained with knowledge of Y = y for a subjectwith baseline risk factors X. The notion is commonly used inclinical medicine to quantify the increment in risk predictiondue to Y. It is contrasted here with the notion of covariate-adjustedeffect of Y in the augmented risk model. We also propose methodsfor making inference about DLR_X(y). Case–control studydesigns are accommodated. The methods provide a mechanism toinvestigate if the predictive information in Y varies with baselinecovariates. In addition, we show that when combined with a baselinerisk model and information about the population distributionof Y given X, covariate-specific predictiveness curves can beestimated. These curves are useful to an individual in decidingif ascertainment of Y is likely to be informative or not forhim. We illustrate with data from 2 studies: one is a studyof the performance of hearing screening tests for infants, andthe other concerns the value of serum creatinine in diagnosingrenal artery stenosis.     

Intergeneric and Interspecific Relationships in Araceae tribe Caladieae and Development of Molecular Markers using Amplified Fragment Length Polymorphism (AFLP)

Since amplified fragment length polymorphism (AFLP) analysishas proved useful in distinguishing cultivars of Caladium, itwas used to assess the status of species of Caladium vs. Xanthosoma,both in tribe the Caladieae, and to reassess the position ofHapaline in the same tribe. AFLP analysis using three primercombinations was carried out on four species of Caladium(C.bicolor, C. humboldtii, C. lindenii and C. schomburgkii). Resultsshowed that AFLP can distinguish between the different speciesby their unique and different banding patterns. AFLP analysisconfirmed that C. humboldtii is a species distinct from C. bicolorand that C. lindenii is a true Caladium species and does notbelong to Xanthosoma. UPGMA cluster analysis showed that C.bicolor and C. schomburgkii are most similar and that C. humboldtiiis closer to the C. bicolor / C. schomburgkii cluster comparedwith C. lindenii. Genetic relationships between Caladium, Xanthosoma,Hapaline, Alocasia and Protarum were also examined by AFLP analysisusing eight primer combinations. Several useful molecular markerswere specific either to Caladium orXanthosoma , so that AFLPcan be used to distinguish species of these two genera. Geneticanalysis of the genera examined confirms that the Caladieaeand Colocasieae tribes are distinct and that Hapaline fallswithin the tribe Caladieae and that Protarum is most distantfrom all the genera examined. Copyright 2000 Annals of BotanyCompany Araceae, Caladium, Xanthosoma, Hapaline, Alocasia, Protarum, AFLP DNA fingerprinting, diversity, AFLP markers     

Addenda Clavariacea. III

1. The following noveltiea are described, with notes on otherspecies of their genera : Aphelaria subgen. Tremellodendropsis for the A. tuberosa alliancewith subtremellaceous basidia: A. amboinensis (Lév.)comb. nov. Chaetotyphula gelatinosa sp. nov. and C. tetraspora sp. nov.from Tropical America, whence C. hyalina (Jungh.) Corner isalso recorded. Clavariadelphus junceus (Fr.) Corner is recorded from Brazil. Mucronella flava sp. nov. from Iowa. Phaeoapheloria austra1iensis gen. et sp. nov. is intermediatebetween Aphelaria and stereoid fungi. Pistillaria trispora sp. nov. from Iowa: P. tucumanensis (Speg.)comb. nov. for Typhula tucumanensis Speg. Phistillina calyx Heim is excluded as marasmioid. 2. The Physalacria-subseriea is reviewed, and the followingare described aa new: Hormomitaria albidula sp. nov. from Brazil Pseudotyhula gen. nov. from West Africa: P. ochracea sp. nov.as the typespecies : P. tenuipes (Lloyd) comb. nov. (= Mucronellatenuipes Lloyd).     

The GUS reporter-aided analysis of the promoter activities of Arabidopsis ACC synthase genes AtACS4, AtACS5, and AtACS7 induced by hormones and stresses

Ethylene biosynthesis in higher plants is regulated developmentallyand environmentally. To investigate the regulation of ACC synthasegene expression, the promoters of Arabidopsis ACS genes, AtACS4,AtACS5, and AtACS7, were fused to a GUS reporter gene, and therecombinant transgenes were introduced into Arabidopsis to producethree groups of AtACS::GUS transgenic plants. Histochemic andfluorometric study of these transgenic plants revealed thatpromoters of AtACS4, AtACS, and AtACS7 are all active in dark-germinatedseedlings. AtACS5 has the highest promoter activity in leavesof 2-week-old light-grown seedlings among the three AtACS genesstudied. In the mature leaves, AtACS4 and AtACS7 genes are expressedin both veins and areoles, whereas AtACS5 is expressed at ahigher level in the areoles and epidermal cells surroundingtrichomes. The promoter activities of all these AtACS genesare found in the reproductive organs. AtACS5 and AtACS7 arehighly expressed in petals, sepals, carpels, stamens, caulineleaves, inflorescence stems, and siliques, while AtACS4 expressionis undetectable in the petals of open flowers. All three AtACSgenes are expressed in root tissue. In the 2-week-old light-grownArabidopsis, the AtACS4 promoter is responsive to the planthormones IAA, ethylene, and ABA, and to darkness and wounding;the AtACS5 promoter to IAA, ABA, salt, high temperature, andwounding; and the AtACS7 promoter to GA₃, ethylene, and ABA,and to darkness and salt. Low-temperature treatment abolishesthe darkness-induced AtACS7 gene expression, but not that ofAtACS4. Each AtACS gene has a unique expression profile duringgrowth and development. It appears that at any developmentalstage or any growth period of Arabidopsis, there is always amember of AtACS multigene family that is actively expressed. Key words: ACC synthase, Arabidopsis, ethylene, gene expression, GUS histochemical staining, reporter, stress treatments     

Structure of the dnaA region of the endosymbiont, Buchnera aphidicola, of aphid Schizaphis graminum

Buchnera aphidicola is an intracellular prokaryote (endosymbiont)that lives in the body cavity of the aphid. Phylogenetic studiesindicated that it is closely related to Escherichia coli andmembers of Enterobacteria. The gene order of the region containingthe dnaA gene is well conserved in many bacteria. Seven genesof the endosymbiont of the aphid Schizaphis graminum, gyrB,dnaN, dnaA, rpmH, rnpA, yidD, and 60K, were found to be homologousin sequence and relative location to those of E. coli. We havefurther sequenced the region downstream of the 60K gene to elucidatethe boundary of the conserved region, and found that one moregene, thdF , is conserved. The comparison of gene organizationsof the dnaA region of the related bacteria supported the closephylogenetic relationship of B. aphidicola to E. coli. In addition,we have identified groES and groEL genesnext to the thdF gene.GroEL protein was reported to be expressed at an elevated levelin the endosymbionts of aphids, and is considered to play animportant role in their association with the aphid host. Comparisonof the structure of the groE operon with that of the endosymbiontof the aphid Acyrthosiphon pisum revealed the conservation ofa sequence resembling the E. coli consensus heat shock promoter,and this sequence may be responsible for the high expressionof the groEL gene in aphid endosymbionts.     

Energetic constraints and foraging efficiency

Previous research considers foraging options that differ interms of their gross rate of gain b and rate of energy expenditurec. This research argues that maximizing efficiency b/c willmaximize net energetic gain when there is an upper limit onthe amount of energy that can be assimilated. This analysisdoes not include the expenditure during the time for which theanimal is unable to forage because of this constraint. Whenthis expenditure is included, maximizing efficiency is no longeroptimal. Instead the best feeding option is the one with thehighest value of b/(c – c₁), where c, is the metabolicrate when the animal is not foraging.     

ON THE STATUS OF THE GENERIC NAMES OF THE NUDIBRANCH GENERA CATRIONA, CRATENA, HERVIA, RIZZOLIA AND TRINCHESIA

The genus Catriona Winckworth (1941) is synonymous with TrinchesiaPruvot-Fol (1951) but not with Trinchesia von Jhering (1879). It has priority over Trinchesia Pruvot-Fol. The genus Cratena Bergh (1864) is valid and synonymous withRizzolia Trinchese (1877) but not with Hervia Bergh (1871). The genus Hervia Bergh (1871) is synonymous with Facelina Alderand Hancock (1855), but not all species of Hervia can be includedin the latter genus, and these should, therefore, be distributedamong other genera, some of which are listed. (Received 8 October 1954;     

Leaf Survival and Evolution in Betulaceae

Studies on the changes in leaf number of 12 species of Betulaceaewere carried out by repeated observations during several years.The inner structure of the winter buds of these species wasalso examined. The periods of leaf emergence were long in Alnusand Betula, intermediate in Corylus and short in Ostrya andCarpinus. A heavy summer leaf fall is characteristic only ofthe Gymnothyrsus subgenus of Alnus. One lamina and two stipulesis the basic unit constituting the winter buds. Only the budsof Gymnothyrsus are composed of several of these units. In theAlnaster subgenus of Alnus, Betula and Corylus, there are oneor two scales that seem to have originated from the two stipulesremaining after reduction of the lamina. Eight and 24 scalesof similar origin were found in Ostrya and Carpinus respectively.A common ancestral species having the following primitive charactersis proposed: shoot constituted only of the equal-sized units,period of leaf emergence long, and leaf fall usually occurs.Alnus (Gymnothyrsus) is assumed to be the most primitive typeas it has many characters similar to those of the proposed ancestralspecies. Carpinus is assumed to be the most advanced group.The leaf survivorship curve is assumed to have changed fromthe primitive bell-shaped to an advanced trapezoid concurrentwith an increase in the number of bud scales. Betulaceae, Alnus, Betula, Carpinus, Corylus, Ostrya, leaf survival, leaf emergence, stipules, winter buds, evolution     

THE GENUS TRICOLIA IN THE EASTERN ATLANTIC AND THE MEDITERRANEAN

The genus Tricolia(Phasianellidae) in the Eastern Atlantic andMediterranean is reviewed on the bases of radular morphology,shell characters and polychromatism. The taxa included within the T. pullus (L.) group are not clearlyseparable and are treated as geographical subspecies:T. pulluspullus (L.), T. pullus picta (da Costa), T. pullus azorica (Dautzenberg),T. pullus canarica Nordsieck. The case of T. tenuis (Michaud)is problematic since it is clearly separable from sympatricT. pullus pullus in most parts of the Mediterranean but transitionalto T. pullus picta, towards the Atlantic. Other taxa are considered as having specific status since theyare consistently separable when found in sympatric populations.These include T. speciosa (Muhlfeldt), T. miniata (Monterosato),T. tingitana n.sp., T. petiti (Craven), T. nordsiecki (Talavera)and T. algoidea (Pallary). The last two species are stated forthe first time as belonging to the Phasianellidae. The genusEpheriella Pallary, based on T. algoidea, is synonymized withTricolia. (Received 6 April 1981;     

FLC or not FLC: the other side of vernalization

Vernalization is the promotion of the competence for floweringby long periods of low temperatures such as those typicallyexperienced during winters. In Arabidopsis, the vernalizationresponse is, to a large extent, mediated by the repression ofthe floral repressor FLC, and the stable epigenetic silencingof FLC after cold treatments is essential for vernalization.In addition to FLC, other vernalization targets exist in Arabidopsis.In grasses, vernalization seems to be entirely independent ofFLC. Here, the current understanding of FLC-independent branchesof the vernalization pathway in Arabidopsis and vernalizationwithout FLC in grasses is discussed. This review focuses onthe role of AGL19, AGL24, and the MAF genes in Arabidopsis.Interestingly, vernalization acts through related molecularmachineries on distinct targets. In particular, protein complexessimilar to Drosophila Polycomb Repressive Complex 2 play a prominentrole in establishing an epigenetic cellular memory for cold-regulatedexpression states of AGL19 and FLC. Finally, the similar networktopology of the apparently independently evolved vernalizationpathways of grasses and Arabidopsis is discussed. Key words: AGL19, Arabidopsis, chromatin, epigenetics, FLC, flowering time, polycomb, PRC2, vernalization Received 19 December 2007; Revised 11 February 2008 Accepted 15 February 2008     

Cytochrome components of green alga, Bryopsis maxima

Five soluble cytochromes were isolated and were partially purifiedfrom Bryopsis maxima: Cytochrome b-562 is slightly autoxidizable and has a midpointredox potential of +175 mV at pH 7.0. Its molecular weight isclose to 30,000 as estimated by dextran gel filtration. Cytochrome b-555 is autoxidizable and can be reduced by dithionitebut not by ascorbate. Cytochrome c-549 is a basic protein. It is slightly autoxidizableand reducible with either ascorbate or dithionite. Cytochrome c-549_(LP) is autoxidizable and reducible with dithionitebut not with ascorbate. The reduced cytochrome combines withcarbon monoxide. Cytochrome c-553 is the f-type one, which was reported by Sugimuraet al. (1968). ¹ This paper is dedicated to the memory of the late Prof. AtusiTakamiya at Toho University. (Received September 10, 1976; )     

COMPETITIVE INTERACTIONS BETWEEN THE LAND SNAILS THEBA PISANA (MULLER) AND CERNUELLA VIRGATA (DA COSTA) FROM SOUTH AUSTRALIA

Changing distribution patterns of T. pisana and C. virgata atcoastal sites around South Australia suggest T. pisana is replacingC. virgata in some areas Under laboratory conditions C. virgata exhibits reduced survivaland growth, is less active and feeds less when kept in the presenceof T. pisana adults and/or their mucus and excrement. If thearea of cooccurrence is large relative to the population size,C. virgata may be displaced to the less favourable habitats.No inhibition of the fecundity of C. virgata was seen. Bothspecies also depress feeding intraspecifically T. pisana also preys on C. virgata under some conditions, notnecessarily when food is limiting It is suggested that these mechanisms act within co-occurringpopulations of the species and result in the exclusion of C.virgata from some areas ^*Present address: 9 Torrens Ave, West Hindmarsh, South Auustralia,5007 (Received 1 November 1986; accepted 15 November 1987)     

Leaf and Flower Development in Pea (Pisum sativum L.): Mutants cochleata andunifoliata

The stipule mutant cochleata(coch) and the simple-leaf mutantunifoliata(uni) are utilized to increase understanding of the controlof compound leaf and flower development in pea. The phenotypeof the coch mutant, which affects the basal stipules of thepea leaf, is described in detail. Mutant coch flowers have supernumeraryorgans, abnormal fusing of flower parts, mosaic organs and partialmale and female sterility. The wild-type Coch gene is shownto have a role in inflorescence development, floral organ identityand in the positioning of leaf parts. Changes in meristem sizemay be related to changes in leaf morphology. In the coch mutant,stipule primordia are small and their development is retardedin comparison with that of the first leaflet primordia. Thediameter of the shoot apical meristem of the uni mutant is approx.25% less than that of its wild-type siblings. This is the firsttime that a significant difference in apical meristem size hasbeen observed in a pea leaf mutant. Genetic controls in thebasal part of the leaf are illustrated by interactions betweencoch and other mutants. The mutantcoch gene is shown to changestipules into a more ‘compound leaf-like’ identitywhich is not affected by thestipules reduced mutation. The interactionof coch and tendril-less(tl) genes reveals that the expressionof the wild-type Tl gene is reduced at the base of the leaf,supporting the theories of gradients of gene action. Copyright2001 Annals of Botany Company Pisum sativum, garden pea, leaf morphogenesis, compound leaf, leaf mutants, flower morphology