87 research outputs found
Ecological niche and potential geographic distribution of the invasive fruit fly *Bactrocera invadens* (Diptera, Tephritidae)
Two correlative approaches to the challenge of ecological niche modeling (genetic algorithm, maximum entropy) were used to estimate the potential global distribution of the invasive fruit fly, Bactrocera invadens, based on associations between known occurrence records and a set of environmental predictor variables. The two models yielded similar estimates, largely corresponding to Equatorial climate classes with high levels of precipitation. The maximum entropy approach was somewhat more conservative in its evaluation of suitability, depending on thresholds for presence/absence that are selected, largely excluding areas with distinct dry seasons; the genetic algorithm models, in contrast, indicate that climate class as partly suitable. Predictive tests based on independent distributional data indicate that model predictions are quite robust. Field observations in Benin and Tanzania confirm relationships between seasonal occurrences of this species and humidity and temperature
Pupae transplantation to boost early colony growth in the weaver ant Oecophylla longinoda Latreille (Hymenoptera: Formicidae)
Oecophylla ants are currently used for biological control in fruit plantations in Australia, Asia and Africa and for protein production in Asia. To further improve the technology and implement it on a large scale, effective and fast production of live colonies is de¬sirable. Early colony development may be artificially boosted via the use of multiple queens (pleometrosis) and/or by adoption of foreign pupae in developing colonies. In the present experiments, we tested if multiple queens and transplantation of pupae could boost growth in young Oecophylla longinoda colonies. We found out that colonies with two queens artificially placed in the same nest, all perished due to queen fighting, suggesting that pleometrosis is not used by O. longinoda in Benin. In contrast, pupae transplantation resulted in highly increased growth rates, as pupae were readily adopted by the queens and showed high survival rates (mean = 92%). Within the 50-day experi¬ment the total number of individuals in colonies with 50 and 100 pupae transplanted, increased with 169 and 387%, respectively, compared to colonies receiving no pupae. This increase was both due to the individuals added in the form of pupae but also due to an increased per capita brood production by the resident queen, triggered by the adopted pupae. Thus pupae transplantation may be used to shorten the time it takes to produce weaver ant colonies in ant nurseries, and may in this way facilitate the imple-mentation of weaver ant biocontrol in West Africa
Founding weaver ant queens (Oecophylla longinoda) increase production and nanitic worker size when adopting nonnestmate pupae
Weaver ants (Oecophylla longinoda Latreille) are used commercially to control pest insects
and for protein production. In this respect fast colony growth is desirable for managed
colonies. Transplantation of non-nestmate pupae to incipient colonies has been shown to
boost colony growth. Our objectives were to find the maximum number of pupae a founding
queen can handle, and to measure the associated colony growth. Secondly, we tested if
transplantation of pupae led to production of larger nanitic workers (defined as unusually
small worker ants produced by founding queens in their first batch of offspring). Forty-five
fertilized queens were divided into three treatments: 0 (control), 100 or 300 non-nestmate
pupae transplanted to each colony. Pupae transplantation resulted in highly increased growth
rates, as pupae were readily adopted by the queens and showed high proportions of surviving
(mean = 76%). However, survival was significantly higher when 100 pupae were transplanted
compared to transplantation of 300 pupae, indicating that queens were unable to handle 300
pupae adequately and that pupae require some amount of nursing. Nevertheless, within the
60-day experiment the transplantation of 300 pupae increased total colony size more than 10-
fold whereas 100 pupae increased the size 5.6 fold, compared to control. This increase was
due not only to the individuals added in the form of pupae but also to an increased per capita
brood production by the resident queen, triggered by the adopted pupae. The size of hatching
pupae produced by the resident queen also increased with the number of pupae transplanted,
leading to larger nanitic workers in colonies adopting pupae. In conclusion, pupae
transplantation may be used to produce larger colonies with larger worker ants and may thus
reduce the time to produce weaver ant colonies for commercial purposes. This in turn may
facilitate the implementation of the use of weaver ants.Weaver ants (Oecophylla longinoda Latreille) are used commercially to control pest insects
and for protein production. In this respect fast colony growth is desirable for managed
colonies. Transplantation of non-nestmate pupae to incipient colonies has been shown to
boost colony growth. Our objectives were to find the maximum number of pupae a founding
queen can handle, and to measure the associated colony growth. Secondly, we tested if
transplantation of pupae led to production of larger nanitic workers (defined as unusually
small worker ants produced by founding queens in their first batch of offspring). Forty-five
fertilized queens were divided into three treatments: 0 (control), 100 or 300 non-nestmate
pupae transplanted to each colony. Pupae transplantation resulted in highly increased growth
rates, as pupae were readily adopted by the queens and showed high proportions of surviving
(mean = 76%). However, survival was significantly higher when 100 pupae were transplanted
compared to transplantation of 300 pupae, indicating that queens were unable to handle 300
pupae adequately and that pupae require some amount of nursing. Nevertheless, within the
60-day experiment the transplantation of 300 pupae increased total colony size more than 10-
fold whereas 100 pupae increased the size 5.6 fold, compared to control. This increase was
due not only to the individuals added in the form of pupae but also to an increased per capita
brood production by the resident queen, triggered by the adopted pupae. The size of hatching
pupae produced by the resident queen also increased with the number of pupae transplanted,
leading to larger nanitic workers in colonies adopting pupae. In conclusion, pupae
transplantation may be used to produce larger colonies with larger worker ants and may thus
reduce the time to produce weaver ant colonies for commercial purposes. This in turn may
facilitate the implementation of the use of weaver ants.Weaver ants (Oecophylla longinoda Latreille) are used commercially to control pest insects
and for protein production. In this respect fast colony growth is desirable for managed
colonies. Transplantation of non-nestmate pupae to incipient colonies has been shown to
boost colony growth. Our objectives were to find the maximum number of pupae a founding
queen can handle, and to measure the associated colony growth. Secondly, we tested if
transplantation of pupae led to production of larger nanitic workers (defined as unusually
small worker ants produced by founding queens in their first batch of offspring). Forty-five
fertilized queens were divided into three treatments: 0 (control), 100 or 300 non-nestmate
pupae transplanted to each colony. Pupae transplantation resulted in highly increased growth
rates, as pupae were readily adopted by the queens and showed high proportions of surviving
(mean = 76%). However, survival was significantly higher when 100 pupae were transplanted
compared to transplantation of 300 pupae, indicating that queens were unable to handle 300
pupae adequately and that pupae require some amount of nursing. Nevertheless, within the
60-day experiment the transplantation of 300 pupae increased total colony size more than 10-
fold whereas 100 pupae increased the size 5.6 fold, compared to control. This increase was
due not only to the individuals added in the form of pupae but also to an increased per capita
brood production by the resident queen, triggered by the adopted pupae. The size of hatching
pupae produced by the resident queen also increased with the number of pupae transplanted,
leading to larger nanitic workers in colonies adopting pupae. In conclusion, pupae
transplantation may be used to produce larger colonies with larger worker ants and may thus
reduce the time to produce weaver ant colonies for commercial purposes. This in turn may
facilitate the implementation of the use of weaver ants.Weaver ants (Oecophylla longinoda Latreille) are used commercially to control pest insects
and for protein production. In this respect fast colony growth is desirable for managed
colonies. Transplantation of non-nestmate pupae to incipient colonies has been shown to
boost colony growth. Our objectives were to find the maximum number of pupae a founding
queen can handle, and to measure the associated colony growth. Secondly, we tested if
transplantation of pupae led to production of larger nanitic workers (defined as unusually
small worker ants produced by founding queens in their first batch of offspring). Forty-five
fertilized queens were divided into three treatments: 0 (control), 100 or 300 non-nestmate
pupae transplanted to each colony. Pupae transplantation resulted in highly increased growth
rates, as pupae were readily adopted by the queens and showed high proportions of surviving
(mean = 76%). However, survival was significantly higher when 100 pupae were transplanted
compared to transplantation of 300 pupae, indicating that queens were unable to handle 300
pupae adequately and that pupae require some amount of nursing. Nevertheless, within the
60-day experiment the transplantation of 300 pupae increased total colony size more than 10-
fold whereas 100 pupae increased the size 5.6 fold, compared to control. This increase was
due not only to the individuals added in the form of pupae but also to an increased per capita
brood production by the resident queen, triggered by the adopted pupae. The size of hatching
pupae produced by the resident queen also increased with the number of pupae transplanted,
leading to larger nanitic workers in colonies adopting pupae. In conclusion, pupae
transplantation may be used to produce larger colonies with larger worker ants and may thus
reduce the time to produce weaver ant colonies for commercial purposes. This in turn may
facilitate the implementation of the use of weaver ants
Impact of African weaver ant nests [Oecophylla longinoda Latreille (Hymenoptera: Formicidae)] on mango [Mangifera indica L. (Sapindales: Anacardiaceae)] leaves
Oecophylla
ants are appreciated for their control of pests in plantation crops. However,
the ants ? nest building may have negative impacts on trees. In this study we tested
the effect of ant densities and nest building on the leaf performance of mango trees.
Trees were divided into three groups: trees without ants, trees with low and trees with
high ant densities. Subsequently, the total number of leaves, the proportion of leaves
used for nest construction, and tree growth was compared between these groups. The
percentage of leaves used for nests was between 0.42-1.2 % (mean = 0.7%±0.02) and
the total number of leaves and tree growth was not significantly different between
trees with and without ants. Further, leaf performance was compared between shoots
with and without ant nests and between leaves in or outside ant nests. The number
of leaves and lost leaves per shoot, leaf size
, leaf
condition (withered), leaf longevity
and hemipteran infection was compared between groups. In the dry season nest-shoots
held more leaves than shoots without nests despite nest-shoots showed more lost
leaves. Leaves in nests were smaller than other leaves, more likely to wither and more
often infested with scales. However, smaller nest-leaf size was probably due to the ants ?
preference for young leaves and the higher incidence of withering resulting as leaves in
nests cannot fall to the ground. In conclusion, the costs associated to ant nests were low
and did not affect the overall number of leaves per tree nor tree growth.Oecophylla
ants are appreciated for their control of pests in plantation crops. However,
the ants ? nest building may have negative impacts on trees. In this study we tested
the effect of ant densities and nest building on the leaf performance of mango trees.
Trees were divided into three groups: trees without ants, trees with low and trees with
high ant densities. Subsequently, the total number of leaves, the proportion of leaves
used for nest construction, and tree growth was compared between these groups. The
percentage of leaves used for nests was between 0.42-1.2 % (mean = 0.7%±0.02) and
the total number of leaves and tree growth was not significantly different between
trees with and without ants. Further, leaf performance was compared between shoots
with and without ant nests and between leaves in or outside ant nests. The number
of leaves and lost leaves per shoot, leaf size
, leaf
condition (withered), leaf longevity
and hemipteran infection was compared between groups. In the dry season nest-shoots
held more leaves than shoots without nests despite nest-shoots showed more lost
leaves. Leaves in nests were smaller than other leaves, more likely to wither and more
often infested with scales. However, smaller nest-leaf size was probably due to the ants ?
preference for young leaves and the higher incidence of withering resulting as leaves in
nests cannot fall to the ground. In conclusion, the costs associated to ant nests were low
and did not affect the overall number of leaves per tree nor tree growth
Innovative Approaches to Analysing Carbon Sequestration as a Mitigation Strategy in Tropical Pasture Landscapes in Two Emblematic Contexts, the Amazon and the West African Sahel
The relationship between ruminant production systems and climate change is complex. As a major contributor to greenhouse gas (GHG) emissions, the sector has been the subject of considerable controversy, with particularly severe criticism in the 2000s. However, ten years ago, the attitude towards grazing lands began to change. Their efficient use of non-renewable energy and their contribution to carbon (C) sequestration were considered as key factors in the new environmental challenge. The reality of this mitigation potential was recently called into question once again in the global agriculture and climate change debate, including that of sequestration in the soil where grazing lands occupy a major position (30-40% of the land surface representing 30% of the soil organic C of the world). Few scientific references are available on these questions in tropical regions, and the standard metrics and methods used may turn out to be unsuitable for the correct evaluation of grazed ecosystems in these regions. Significant work is therefore required to establish baselines and design strategies to ensure sustainable grazing in these regions where the global sequestration potential is high relative to the surface areas concerned.
To contribute to this debate, we focus on mitigation options offered by rangelands and grasslands and their management in two emblematic tropical contexts, humid and dry tropics, where field studies have been based on original and holistic approaches at different levels. In Amazonia, if curbing deforestation remains a priority, it needs to be accompanied by sustainable management of deforested areas. In the French Amazon (French Guiana), monitoring fields using chronosequences and flux towers has produced scientific knowledge on the significant mitigation capacities of grassland ecosystems. In the Brazilian Amazon, the spatial logic of the agro-ecological intensification of forage production has enabled a transition from individual extractive systems to farm management at communal levels. In the West African Sahelian region (Northern Senegal), an integrative study at landscape scale revealed the unexpected capacity of soil and shrubs for C sequestration that can offset the GHG emissions for which pastoralism in dry tropical zones is usually blamed
PIF4 enhances DNA binding by CDF2 to co-regulate target gene expression and promote Arabidopsis hypocotyl cell elongation
How specificity is conferred within gene regulatory networks is an important problem in biology. The basic helix–loop–helix PHYTOCHROME-INTERACTING FACTORs (PIFs) and single zinc-finger CYCLING DOF FACTORs (CDFs) mediate growth responses of Arabidopsis to light and temperature. We show that these two classes of transcription factor (TF) act cooperatively. CDF2 and PIF4 are temporally and spatially co-expressed, they interact to form a protein complex and act in the same genetic pathway to promote hypocotyl cell elongation. Furthermore, PIF4 substantially strengthens genome-wide occupancy of CDF2 at a subset of its target genes. One of these, YUCCA8, encodes an auxin biosynthesis enzyme whose transcription is increased by PIF4 and CDF2 to contribute to hypocotyl elongation. The binding sites of PIF4 and CDF2 in YUCCA8 are closely spaced, and in vitro PIF4 enhances binding of CDF2. We propose that this occurs by direct protein interaction and because PIF4 binding alters DNA conformation. Thus, we define mechanisms by which PIF and CDF TFs cooperate to achieve regulatory specificity and promote cell elongation in response to light
The potential distribution of Bactrocera dorsalis: Considering phenology and irrigation patterns
A species in the Bactrocera dorsalis (Hendel) complex was detected in Kenya during 2003 and classified as Bactrocera invadens Drew, Tsuruta & White. Having spread rapidly throughout Africa, it threatens agriculture due to crop damage and loss of market access. In a recent revision of the B. dorsalis complex, B. invadens was incorporated into the species B. dorsalis. The potential distribution of B. dorsalis has been previously modelled. However, previous models were based on presence data and did not incorporate information on the seasonal phenology of B. dorsalis, nor on the possible influence that irrigation may have on its distribution. Methyl eugenol-baited traps were used to collect B. dorsalis in Africa. Seasonal phenology data, measured as fly abundance throughout the year, was related to each location's climate to infer climatic growth response parameters. These functions were used along with African distribution records and development studies to fit the niche model for B. dorsalis, using independent global distribution records outside Africa for model validation. Areas at greatest risk of invasion by B. dorsalis are South and Central America, Mexico, southernmost USA, parts of the Mediterranean coast, parts of Southern and Eastern Australia and New Zealand's North Island. Under irrigation, most of Africa and Australia appear climatically suitable. (Résumé d'auteur
Host plant range of a fruit fly community (Diptera: Tephritidae): Does fruit composition influence larval performance?
Background: Phytophagous insects differ in their degree of specialisation on host plants, and range from strictly monophagous species that can develop on only one host plant to extremely polyphagous species that can develop on hundreds of plant species in many families. Nutritional compounds in host fruits affect several larval traits that may be related to adult fitness. In this study, we determined the relationship between fruit nutrient composition and the degree of host specialisation of seven of the eight tephritid species present in La Réunion; these species are known to have very different host ranges in natura. In the laboratory, larval survival, larval developmental time, and pupal weight were assessed on 22 fruit species occurring in La Réunion. In addition, data on fruit nutritional composition were obtained from existing databases. Results: For each tephritid, the three larval traits were significantly affected by fruit species and the effects of fruits on larval traits differed among tephritids. As expected, the polyphagous species Bactrocera zonata, Ceratitis catoirii, C. rosa, and C. capitata were able to survive on a larger range of fruits than the oligophagous species Zeugodacus cucurbitae, Dacus demmerezi, and Neoceratitis cyanescens. Pupal weight was positively correlated with larval survival and was negatively correlated with developmental time for polyphagous species. Canonical correspondence analysis of the relationship between fruit nutrient composition and tephritid survival showed that polyphagous species survived better than oligophagous ones in fruits containing higher concentrations of carbohydrate, fibre, and lipid. Conclusion: Nutrient composition of host fruit at least partly explains the suitability of host fruits for larvae. Completed with female preferences experiments these results will increase our understanding of factors affecting tephritid host range. (Résumé d'auteur
Using classification and regression tree modelling to investigate response shift patterns in dentine hypersensitivity
BACKGROUND: Dentine hypersensitivity (DH) affects people's quality of life (QoL). However changes in the internal meaning of QoL, known as Response shift (RS) may undermine longitudinal assessment of QoL. This study aimed to describe patterns of RS in people with DH using Classification and Regression Trees (CRT) and to explore the convergent validity of CRT with the then-test and ideals approaches. METHODS: Data from an 8-week clinical trial of mouthwashes for dentine hypersensitivity (n = 75) using the Dentine Hypersensitivity Experience Questionnaire (DHEQ) as the outcome measure, were analysed. CRT was used to examine 8-week changes in DHEQ total score as a dependent variable with clinical status for DH and each DHEQ subscale score (restrictions, coping, social, emotional and identity) as independent variables. Recalibration was inferred when the clinical change was not consistent with the DHEQ change score using a minimally important difference for DHEQ of 22 points. Reprioritization was inferred by changes in the relative importance of each subscale to the model over time. RESULTS: Overall, 50.7% of participants experienced a clinical improvement in their DH after treatment and 22.7% experienced an important improvement in their quality of life. Thirty-six per cent shifted their internal standards downward and 14.7% upwards, suggesting recalibration. Reprioritization occurred over time among the social and emotional impacts of DH. CONCLUSIONS: CRT was a useful method to reveal both, the types and nature of RS in people with a mild health condition and demonstrated convergent validity with design based approaches to detect RS
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