Ecology and Impacts of the Invasive Species, Lantana camara, in a Social-Ecological System in South India: Perspectives from Local Knowledge

We explored how the forest-dwelling Soliga community of South India views and explains biological invasions, and how local knowledge can inform scientific knowledge on biological invasions. We used an interview schedule with open-ended questions to solicit Soliga opinion on Lantana camara (lantana) invasion. The Soliga cited three reasons for lantana spread: its prolific fruit output and wide seed dispersal, change in fire management, and historical extraction of grass and bamboo. The Soliga believe that lantana invasion has had negative effects on the ecosystem and their livelihoods. Tabling scientific knowledge with local knowledge has improved our understanding of lantana invasion. The role of existing lantana in colonizing neighboring areas, and the response of native tree communities to lantana were common to both local and scientific sources. However, the Soliga view provides a more nuanced perspective of the lantana-fire relationship (contextually based on lantana density) with fires suppressing lantana when lantana density was low. This is contrary to views held by foresters and biologists, that fires are uniformly detrimental and promote lantana. Our study shows that examining Soliga observations has improved understanding of the invasion process and presents avenues for future lantana management.     

Development of pycnium in the genus Ravenelia

The development of pycnia in Ravenelia breyniae Sydow, R. emblicae Sydow and R. taslimii Mundkur possessing intraepidermal, subepidermal and subcuticular pycnia respectively are traced. The 3 types of pycnia are simple and their development is characteristic for each type. Ontogeny of pycnia suggests the key position of the genus Ravenelia Berkeley in the evolutionary line from the Melampsoraceae to the Pucciniaceae in the Uredinales.     

Cloning and complete sequence characterization of two gypsy moth aminopeptidase-N cDNAs, including the receptor for Bacillus thuringiensis Cry1Ac toxin.

The complete cDNAs corresponding to two distinct gypsy moth (Lymantria dispar) larval gut aminopeptidases, APN1 and lambda APN2, were cloned and sequenced. The 3.4 kilobasepair cDNA of APN1 which encodes a 1017 amino acid prepro-protein corresponds to the previously-identified gypsy moth APN (APN-1) that specifically binds the Cry1Ac delta-endotoxin of Bacillus thuringiensis. Analysis of the primary structure of APN1 revealed a cluster of five potential N-linked glycosylation sites near the N-terminus and a C-terminal sequence characteristic of a putative glycosylphosphatidyl-inositol (GPI) anchor signal sequence. The cDNA of APN1 encodes the N-terminal peptide sequence and nine internal sequences obtained from the purified brush border membrane vesicle Cry1Ac receptor by protein sequencing. The lambda APN2 cDNA encodes a shorter protein with 51% similarity to APN1 that also appears to have a GPI anchor signal sequence. Expression of the APN1 cDNA in a baculovirus vector was confirmed by immunoblotting.     

The ‘A’ genome donor of Eleusine coracana (L.) Gaertn. (Gramineae)

Summary In an attempt to discover A and B genome donor(s) to finger millet, Eleusine coracana, or its progenitor species, E. africana (both allotetraploid 2n=4x=36), five diploid species, E. Indica, E. Floccifolia, E. multiflora, E. tristachya and E. intermedia, were crossed to finger millet and its progenitor taxon. Crosses were successful only with E. coracana. Three combinations of triploid hybrids E. coracana x E. indica, E. coracana x E. floccifolia, and E. coracana x E. multiflora were obtained and analysed. Meiotic behaviour was perfectly normal in parental species. The regular number of 18 bivalents in E. coracana, 9 bivalents in E. indica, E. intermedia, E. tristachya and E. floccifolia and 8 bivalents in E. multiflora were invariably noticed. In E. coracana x E. indica hybrids a mean chromosome pairing of 8.84_I+8.80_II+0.03_III+0.10_IV per cell was found. About 86.5% of the cells showed the typical 9_I+9_II configuration, suggesting that E. indica (AA) is one of the diploid genome donors to cultivated species E. coracana. A mean chromosome pairing of 11.08_I+7.63_II+0.16_III+0.04_IV per cell was found in E. coracana x E. floccifolia hybrids. Two to ten bivalents and varying numbers of univalents were seen in 55% of the cells. About 45% of the cells showed the 9_I+9_II configuration. Various evidence suggests that perennial E. floccifolia is a primitive member of the A genome group of Eleusine species, and it may not be a genome donor to E. coracana. In E. coracana x E. multiflora hybrids (2n=26) mean chromosome pairing of 21.45_I+1.97_II+0.13_III+0.04_IV per cell was found. About 91% of the cells were observed to have 20–26 univalents. Only a small percentage of the cells contained bivalents or multivalents. This pairing behaviour indicates that E. multiflora lacks genomic homology with the A or B genome of E. coracana. Genomically E. multiflora is a distinct species and a genomic symbol of C is assigned to it. Identification of the B genome donor species to cultivated millet. E. coracana remains elusive.     

Cutinase in Cryphonectria parasitica, the chestnut blight fungus: suppression of cutinase gene expression in isogenic hypovirulent strains containing double-stranded RNAs.

Plant-pathogenic fungi produce cutinase, an enzyme required to degrade plant cuticles and facilitate penetration into the host. The absence of cutinase or a decrease in its production has been associated with a decrease in pathogenicity of the fungus. A set of isogenic strains of Cryphonectria parasitica, the chestnut blight fungus, was tested for the presence and amounts of cutinase activity. The virulent strain of C. parasitica produced and secreted significantly higher amounts of cutinase than the hypovirulent strains. Use of both nucleic acid and polyclonal antibody probes for cutinase from Fusarium solani f. sp. pisi showed that cutinase in C. parasitica is 25 kDa in size and is coded by a 1.1-kb mRNA. Both mRNA and protein were inducible by cutin hydrolysate, while hypovirulence agents suppressed the level of mRNA and the enzyme. Since all the strains had the cutinase gene, the suppression of expression was due to the hypovirulence agents. The data presented are the first report indicating that hypovirulence agents in C. parasitica regulate a gene associated with pathogenicity in other plant-pathogenic fungi.