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Hormonal regulation of the larval development of Sesamia nonagrioides.Pérez Hedo, Meritxell 02 December 2010 (has links)
Els resultats d'aquesta Tesi posen de manifest el paper del cervell en el control del desenvolupament larvari de Sesamia nonagrioides. Així, S. nonagrioides és el primer lepidòpter on s'ha trobat que es pot desenvolupar de larva a adult sense cervell. Les nostres dades mostren que les mudes depenen de l'alliberament d'ecdisteroides per les glàndules protoràciques (GPs) però poden tenir lloc sense la hormona protoracicotròpica (PTTH) del cervell.Mentre que les larves decapitades (larves sense cervell ni corpora allata, (CA)) pupen, les larves de les que s'ha privat del cervell (però s'ha mantingut el CA) sofreixen sovint varies mudes successives; la primera muda pot ser de larva o pupa segons l'edat a la que la larva ha estat privada del cervell i el fotoperíode al qual la larva s'ha desenvolupat. Moltes de les larves L6 privades del cervell un dia després de la muda van mudar a larva independentment de les condicions de fotoperíode durant el desenvolupament, de dia llarg (DL) o curt (DC), mentre que 5 dies després totes les larves desenvolupades en DL van pupar i les de la mateixa edat però desenvolupades en DC van mudar a larva. Els implants de cervell acceleren les mudes a pupa però no alteren les mudes a larva. S. nonagrioides no sembla tenir cap font alternativa als CA de hormona juvenil (HJ). Les larves decapitades no van mostrar quantitats significades de HJ mentre que les larves privades de cervell van mostrar concentracions que es poden detectar fins i tot 10 dies després de la manipulació quirúrgica, però els implants de cervell no activen els CA essent aparentment neural l'activació d'aquests factors. El cervell podria ser el responsable del manteniment de l'estat larvari per inhibició neural de la pupació; quan les larves d'edat variada van ser privades del cervell, la majoria van pupar. De manera similar, el cervell també podria ser el responsable del manteniment de la diapausa per inhibició de la pupació, conseqüentment, quan les larves van ser privades del cervell (tot mantenint o no els CA) les diferencies entre larves dipausants o no diapausants van desaparèixer.El nivell d'ecdisteroides en les larves decapitades augmentà 10 dies després de la manipulació, aproximadament el temps necessari per a pupar en aquelles larves en absència de HJ, encara que l'extracció de les GPs va impedir la muda, i això probà que la presencia de GPs és essencial per al procés de muda. Les GPs en les larves de S. nonagrioides poden funcionar sense estimulació del cervell i la PTTH pot ser alliberada per una font de fora del cap; a S. nonagrioides hem identificat la PTTH mRNA i una font alternativa en l'intestí. La qPCR confirmà que el gen de la PTTH a S. nonagrioides s'expressa molt al cervell de l'instar 6è amb un màxim al dia 5è i un mínim en la prepupa, però el nivell d'expressió de la PTTH es va detectar també en l'intestí de les larves intactes i encara més en el de las decapitades amb una expressió màxima en la prepupa.La més gran part de les larves decapitades muden a pupa sense cap senyal de desenvolupament d'adult mentre que la majoria de pupes provades de cervell sofreixen metamorfosi a adult, lo que suggereix que la transformació de pupa a adult depèn d'un factor desconegut present en les larves privades de cervell però no en les decapitades. En S. nonagrioides la HJ aplicada tòpicament no solament no va inhibir la metamorfosi de pupa a adult però la pogué haver afavorit mentre que l'aplicació d'un agonista d'ecdisteroides a les pupes no va tenir cap efecte en el desenvolupament d'adult.La ingestió per les larves de S. nonagrioides de quantitats subletals de la proteïna Cry1Ab continguda en les fulles de panís o en la dieta va produir un perllongament del seu desenvolupament acompanyat d'un augment en el nombre de mudes abans de pupar però només en les larves criades en condicions de DL, no en les criades en condicions DC. Aquests resultats són deguts a un augment del nivell de HJ en la hemolimfa de les larves no diapausants (DL) alimentades amb fulles de panís Bt o amb la proteïna Bt afegida a la dieta; pel contrari, no es va detectar el possible lleuger increment de HJ causat per la ingestió de la proteïna Bt en les larves diapausants (DC). A més, l'efecte de la proteïna Bt en la concentració d'ecdisteroides en les larves no diapausants va ser suprimir l'augment de la hormona que era necessari per la pupació i per tant va retardar la pupació en les larves tractades. Aquestes respostes poden ser considerades com un mecanisme de defensa que permet que algunes larves puguin mudar i sobreviure a la ingestió de la toxina. / Los resultados de esta Tesis ponen de manifiesto el papel del cerebro en el control del desarrollo larvario de Sesamia nonagrioides. Así, S. nonagrioides es el primer lepidóptero en el que se demuestra que el desarrollo de larva a adulto puede producirse sin la presencia del cerebro. Nuestros datos demuestran que aunque las mudas dependen de la liberación de ecdisteroides por las glándulas protorácicas (GPs), estas pueden ser activadas sin hormona protoracicotrópica (PTTH) del cerebro.Mientras que las larvas decapitadas (larvas sin cerebro ni corpora allata, (CA)) pupan, las larvas descerebradas, de las que se ha extraído el cerebro pero mantienen el CA, sufren a menudo varias mudas sucesivas, la primera a otra larva o pupa según la edad a la que la larva ha sido desprovista del cerebro y según el fotoperiodo bajo el cual la larva se había desarrollado. Muchas larvas desprovistas del cerebro un día después de la muda a sexto estadio mudan a larva independientemente de las condiciones de fotoperiodo, día largo (DL) o corto (DC), recibidas durante su desarrollo, mientras que 5 días después todas las larvas desarrolladas en día largo puparán y las de la misma edad pero desarrolladas en día corto mudaran a larva. Los implantes de cerebro aceleran las mudas a pupa pero no alteran las mudas a larva. S. nonagrioides no parece tener ninguna fuente de hormona juvenil (HJ) alternativa a los CA. Las larvas decapitadas no mostraron cantidades significativas de HJ mientras que las desprovistas de cerebro mostraron cantidades de HJ detectables incluso 10 días después de la manipulación quirúrgica indicando así que los CA siguieron liberando HJ en ausencia del cerebro. Los implantes de cerebro no activaron los CA por lo que su activación es aparentemente neural. El cerebro debe ser el responsable del mantenimiento del estado larvario por inhibición neural de la pupación ya que cuando se extrajo el cerebro a larvas de diferentes edades la mayoría puparon. De manera similar, el cerebro también debe ser el responsable del mantenimiento de la diapausa ya que cuando las larvas fueron desprovistas del cerebro (manteniendo o no los CA) las diferencias entre larvas dipausantes o no diapausantes desaparecieron.El nivel de ecdisteroides en las larvas decapitadas aumentó 10 días después de la extracción del cerebro, este tiempo es aproximadamente el tiempo que las larvas de último estadio larvario necesitan para pupar. La extracción de las GPs impidió la muda, lo que demuestra que su presencia es esencial para que tenga lugar el proceso de la muda. Ante la evidencia de que las GPs de las larvas de S. nonagrioides podían activarse sin la estimulación por hormona PTTH del cerebro se buscaron fuentes alternativas de la hormona y se identificó PTTH mRNA en el intestino de la larva. La qPCR confirmó que el gen de la PTTH en S. nonagrioides se expresa de forma elevada en el cerebro de la larva de 6º estadio con un máximo el 5º día del mismo y un mínimo en la prepupa, pero la expresión de la PTTH se detectó también en el intestino de las larvas intactas y mucho más en las decapitadas con máxima expresión en el periodo de prepupa.De forma general se asume que la metamorfosis pupa-adulto en los insectos se produce en ausencia de HJ y en el caso de S. nonagrioides la mayoría de las larvas decapitadas mudan a pupa sin mostrar posteriormente ningún indicio de desarrollo a adulto mientras que la mayoría de pupas desprovistas de cerebro pero que mantiene su CA sufren metamorfosis a adulto. Este hecho sugirió que la transformación de pupa a adulto en esta especie depende de algún factor presente en las larvas descerebradas pero no en las decapitadas. En S. nonagrioides la HJ aplicada tópicamente no solamente no inhibió la metamorfosis de pupa a adulto sino que la favoreció mientras que la aplicación de un agonista de ecdisteroides a las pupas no tuvo efecto sobre el desarrollo a adulto.La ingestión por las larvas de S. nonagrioides de cantidades subletales de la proteína Cry1Ab contenida en hoja de maíz o en dieta produjo un prolongamiento de su desarrollo acompañado de un aumento en el número de mudas larvarias antes de pupar, pero sólo en las larvas desarrolladas en condiciones de DL, no en las desarrolladas en condiciones de DC. Estos resultados son consecuencia del aumento de HJ en la hemolinfa de las larvas no diapausantes alimentadas con hoja de maíz Bt o con la proteína Bt añadida. Sin embargo, no se detectó el posible ligero aumento de HJ causado por la ingestión de la proteína Bt en las larvas diapausantes (desarrolladas en DC). Otro efecto de la ingestión de la proteína Bt en las larvas no-diapausantes fue suprimir el aumento en la concentración de ecdisteroides necesario para la pupación que por tanto se retrasó en las larvas tratadas. Estas respuestas pueden ser consideradas como un mecanismo de defensa que permite que algunas larvas puedan mudar y así sobrevivir a la ingestión de la toxina. / The results of this Thesis highlight the role of brain in the control of larval development in Sesamia nonagrioides. Thus, S. nonagrioides is the first lepidopteran found to develop from larvae to adult without brain. Our data show that molts depend on the release of ecdysteroids by prothoracic glands (PGs) but they can occur without prothoracicotropic hormone (PTTH) from the brain.While all decapitated larvae (larvae without brain nor corpora allata, (CA)) pupate, the debrained larvae (larvae with no brain but with CA) often undergo several successive molts; first molt could be to larva or pupa, depending on the age at which the larva has been debrained and on the photoperiod under which the larvae have developed: many of the L6 larvae debrained 1 day after molting, molted to larvae independently of the photoperiod conditions of development, long (LD) or short (SD) day, but 5 days later all larvae developed under LD conditions pupated whereas larvae of the same age developd under SD conditions molted to larvae. Brain implants slightly accelerate pupal molts but do not alter the timing of larval molts. S. nonagrioides does not seem to have any alternative source of juvenile hormone (JH) to the CA. Decapitated larvae did not show noticeable amounts of JH while debrained larvae showed detectable concentrations of JH still 10 days after the surgical manipulation but the brain implants do not activate CA, apparently being neural the activation of these factors. The brain might be responsible for larval stage maintenance by neural inhibition of pupation; when the larvae of any age were deprived of their brain, the majority pupated. In the same way, the brain might be also responsible of diapause maintenance by neural inhibition of pupation; consequently, when the larvae were deprived of their brain (maintaining or not their CA) differences between diapausing and non-diapausing larvae disappeared.The level of ecdysteroids in the decapitated larvae increased ten days after manipulation, approximately the time needed to pupate in these larvae in absence of JH, but the removal of PGs prevented molting, proving that the presence of PGs is essential for the molting process. The PGs of S. nonagrioides larvae can function without brain stimulation and PTTH could be released by a source outside the head; in S. nonagrioides we have identified the PTTH mRNA and an alternative PTTH source in the gut. The qPCR confirmed that the PTTH gene of S. nonagrioides is strongly expressed in the brain of the 6th instar with a maximum on day 5 and a minimum in prepupa, but the level of PTTH expression was also detected in the gut of intact and even more in decapitated larvae with a maximum expression in prepupa.Most decapitated larvae molt to pupa with no sign of adult development while the majority of debrained pupae suffer metamorphosis to adult thus suggesting that pupal-adult transformation depends on an unknown factor present in the debrained but not in the decapitated larvae. In S. nonagrioides JH applied topically not only did not inhibit the pupal-adult metamorphosis but could have favored it while the application of an ecdysteroids agonist to the pupae had no effect on the adult development.Ingestion by S. nonagrioides larvae of sub-lethal amounts of Cry1Ab protein contained in maize leaves or the diet produced a prolonged development accompanied by an increase in the number of molts before pupating only in the larvae reared under LD conditions but not in the larvae reared under SD conditions. These results are due to an increase of the level of JH in the hemolymph in the non-diapausing larvae fed with Bt maize leaves or with Bt protein in the diet; on the contrary, in diapausing (SD) larvae the possible low increase of JH due to the Bt toxin ingested was not detected. In addition, the effect of Bt toxin on the ecdysteroids titer in non diapausing larvae was to suppress the increase of the hormone necessary for the pupation of and thus delaying pupation in the treated larvae. These responses may be considered as a defense mechanism allowing some larvae to molt and to survive to the toxin ingestion.
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Evolution of Reproduction and Stress Tolerance in Brachionid RotifersSmith, Hilary April 08 1900 (has links)
Stress can be a driving force for new evolutionary changes leading to local adaptation, or may be responded to with pre-existing, ancestral tolerance mechanisms. Using brachionid rotifers (microzooplankton) as a study system, I demonstrate roles of both conserved physiological mechanisms (heat shock protein induction) and rapid evolution of traits in response to ecologically relevant stressors such as temperature and hydroperiod. Rapid evolution of higher levels of sex and dormancy in cultures mimicking temporary waters represents an eco-evolutionary dynamic, with trait evolution feeding back into effects on ecology (i.e., reduced population growth). I also reveal that prolonged culture in a benign laboratory environment leads to evolution of increased lifespan and fecundity, perhaps due to reduction of extrinsic mortality factors. Potential mechanisms (e.g., hormonal signals) are suggested that may control evolvability of facets of the stress response. Due to prior studies suggesting a role of progesterone signaling in rotifer sex and dormancy, the membrane associated progesterone receptor is assayed as a candidate gene that could show positive selection indicating rapid divergence. Despite some sequence variation that may contribute to functional differences among species, results indicate this hormone receptor is under purifying selection. Detailed analyses of multiple stress responses and their evolution as performed here will be imperative to understanding current patterns of local adaptation and trait-environment correlations. Such research also is key to predicting persistence of species upon introduction to novel habitats and exposure to new stressors (e.g., warming due to climate change). Perhaps one of the most intriguing results of this dissertation is the rapid, adaptive change in levels of sex and dormancy in a metazoan through new mutations or re-arrangements of the genetic material. This suggests species may be able to rapidly evolve tolerance of new stressors, even if standing genetic variation does not currently encompass the suite of alleles necessary for survival.
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Life history evolution in a bivoltine butterflyLarsdotter Mellström, Helena January 2012 (has links)
Evolution is not always straight-forward, as selection pressures may differ between different generations of the same species. This thesis focuses on the evolution of life history of the model species, the Green-veined White butterfly Pieris napi. In central Sweden P. napi has two generations per year. The directly developing summer generation is short-lived and time stressed, compared to the diapausing generation. In paper I polyandry, defined as female mating rate, was shown to differ between generations but was unaffected by environmental factors. In paper II both males and females of the direct developing generation were shown to eclose more immature than the diapausing generation, indicating larval time constraints. Consistent with this, diapausing males mated sooner than direct developers. Directly developing females, however, mated sooner after eclosion than diapausing females, even though they are more immature. This was shown to negatively affect fecundity, but can pay off when the season is short. Paper III shows that directly developing males have less sex pheromones at eclosion than diapausers, and the differences in sex pheromone production is consistent with developmental time constraints and the differences in mating system. In P. napi and other polyandrous butterflies, males transfer a large, nutritious ejaculate at mating. Large ejaculates confer advantages under sperm competition, but as they are costly, males should adjust ejaculate size to the risk of sperm competition. In paper IV we found that males transfer on average 20% larger spermatophores under high male competition than at low competition. The same effect could be observed if we added male sex pheromone to the air in a mating cage without male-male competition. Paper V shows that males of the two generations respond differently to an increase in male-male competition, with diapausing males transferring larger spermatophores than direct developers at high male competition risk. / <p>At the time of the doctoral defence the following paper was unpublished and had a status as follows: Paper 5: Submitted manuscript.</p>
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The mating system and reproduction in the honey possum, Tarsipes rostratus: a life-history and genetical perspectivek.bryant@murdoch.edu.au, Kate Alexandra Bryant January 2004 (has links)
The honey possum Tarsipes rostratus, a marsupial endemic to South-Western Australia, feeds exclusively upon nectar and pollen. It is one of the smallest marsupials, with adult females (8-12g) significantly larger than adult males (6-9g). Honey possum males have the longest sperm (356µm) recorded for any mammaland the testes represent 4.2% body weight, amongst the largest recorded formammal species. These features suggest that sperm competition is an importantpart of the mating system. This study used a combination of field based studies,DNA analysis and histological examination of the female reproductive tract toinvestigate the life history, multiple paternity and reproduction of the honey possum innatural populations in the Fitzgerald River National Park (FRNP), on the south coastof Western Australia.
This study drew upon earlier work on the honey possum in the FRNP in order to describe its life-history. The honey possum is short-lived (1-2 years), and attains sexual maturity whilst still growing. All four teats are occupied after birth, but the litter is reduced to 2 or 3 young during pouch life. The young have a relatively slow rate of
growth. Breeding occurs continuously throughout the year, but is affected by the flowering phenologies of its foodplants. The greatest proportion of females with
pouch-young occurs in winter; there are fewest pouch-young in autumn, a time of year when there is a dearth of flowers. Honey possums are essentially solitary animals, with no structured social unit, and male and female home ranges overlap. In captivity they are largely tolerant of one another, but larger females are behaviorally dominant to smaller females and to males.
The densities and structure of the honey possum populations in the FRNP were analyzed from trapping data collected over 19 years. Population densities fluctuated
significantly from season to season throughout the year, with changes in the flowering food resources available. There were also year-to-year differences in the intensity of those fluctuations, and these were significantly associated with rainfall in the previous year, and probably mediated through a lag effect in the flowering of the honey possums foodplants. The greatest densities of animals occurred over winter. In years following high rainfall, mean winter densities reached 88 individuals per
hectare. The lowest densities occurred in spring, and in years following low rainfall mean spring densities fell to 8 individuals per hectare. Even at these lowest densities, there is still the potential for interaction between males and females. A succession from high to low, then back to high densities was seen during the three years of the present study (2000-2002) and this shadowed a similar succession of changes in rainfall.
The proportion of females with pouch-young was significantly affected by the season, and by rainfall in the previous year. Years following low rainfall had a lower
proportion of females in a condition to breed. The autumn dip in breeding that occurred in all years was exacerbated following dry years. Of those females that did breed in 2001, a time of low resources, there was no difference in the size of the litter compared to 2000 and 2002, times of higher resource availability. The sex-ratio of pouch young was at parity, but there was a slight bias towards males among both juveniles (56%) and adults (58%). This was probably due to the greater movements shown by males. Sex ratios were not affected by changes in rainfall and density. Male-biased dispersal was detected using genetic data and the movement patterns of males showed that they moved greater distances than females during their normal
activity.
Analysis of four microsatellite loci revealed extremely high levels of variation, with 28 to 50 alleles per locus and a mean expected heterozygosity of 0.95. These are
amongst the highest seen in any microsatellite study of vertebrates. There was multiple paternity in 86% litters, using a minimum number of sires per litter method,
and in 95% litters, using an estimated number of sires method based upon the relatedness of litter males. This indicates that multiple mating is frequent in female
honey possums and is evidence for sperm competition. The estimated number of sires in a litter was often three or four. In 41% of cases, the number of sires was less
than the number of young in the litter, indicating that some males were more successful at siring offspring than others. Nevertheless, no more than two offspring in a litter were known to have been sired by the same male. Despite marked fluctuations in density from high in 2000, to low in 2001, then high again in 2002, the level of multiple paternity remained equally high in all years.
Embryonic diapause and female reproduction was investigated in the honey possum. All adult females examined, both with and without pouch-young, were either close to oestrus, had ovulated or were carrying conceptuses. The honey possum has a postpartum
oestrus and it was evident that this occurs approximately 2-4 days after birth. Cleavage and formation of the unilaminar blastocyst appears to occur rapidly over
approximately 5 days. Embryonic diapause proceeded in a two phase manner similar to other small possum species. The unilaminar blastocyst expanded rapidly at first; and then, from about 18-20 days after birth, the diameter of the blastocyst remained constant at approximately 1.2-1.8mm. No growth or development beyond the unilaminar stage was observed during pouch-life. The first signs of reactivation occurred during lactation, after pouch exit, and expansion of the blastocyst only occurred in one post-lactational female. The development of the corpus luteum
appeared different to patterns described for other marsupials, but its formation
coincided with the formation of the unilaminar blastocyst. The diameter of the corpus luteum remained constant throughout diapause. The histology of the reproductive
tract was generally similar to other marsupials. There were no sperm storage crypts in the female reproductive tract.
The length of pouch-life in the honey possum was 55-65 days, and the interval between litters of the same size varied between 65 and 100 days. Embryonic diapause may reduce the time between production of successive litters in the honey possum, but lifetime reproductive potential is reasonably low. Females had up to four litters over the period that they were captured. Thus, each litter represents a substantial proportion (25%) of a females lifetime reproductive output. Reproductive amortization occurred, with 61% loss overall, due to overproduction of ova, loss of conceptuses and reduction of the litter during lactation.
The behavioural dominance of females suggests that multiple mating is an active strategy, and this presumably allows the genetic quality of their offspring to be maximized. Males that succeed in sperm competition may be of better intrinsic quality. Overproduction of conceptuses by females presents the opportunity for them to select those fertilized by intrinsically viable males or genetically compatible males. Sexually active males are present all year round. Females were not synchronous in
their sexual receptivity, and this would lead to a skewed operational sex ratio, with more reproductive males than oestrous females. Since adult males are significantly
smaller than adult females and possess no ornaments or armaments, it is unlikely that males overtly fight for access to females. Rather, males appear to monitor the
reproductive status of females through smell, and probably compete in their ability to locate oestrous females. The risk and intensity of sperm competition is high, sexual
selection for a large investment in spermatogenesis is evident and competition after copulation is probably an important factor in the mating system. It is likely that males, as well as females mate multiply, and the mating system is promiscuous.
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Regulace diapauzy u bázlivce kukuřičného (\kur{Diabrotica virgifera virgifera} LeConte) / Regulation of diapause in the western corn rootworm (\kur{Diabrotica virgifera virgifera} LeConte)HOUFKOVÁ, Kateřina January 2015 (has links)
The thesis aims to optimize the methods of laboratory culture and to fill in the gaps in knowledge of D. virgifera virgifera ecophysiology. The experiments on embryology and development proved that the diapause of D. virgifera virgifera is of obligatory type and can be terminated by exposure to long-day conditions (20:4; photo : scotophase) and constant temperature of 25 °C. Approximately 10% of eggs completed the development to adults within 4 months. Besides numerous other environmental conditions that are discussed, temperature seems to be a key factor influencing longevity in this pest. Higher temperature of 25 °C prolonged survival by more than 20 days in 2015, compared to 22 °C in 2014.
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Embryonální vývoj neoplozených vajíček bource morušového / Embryonic development of the unfertilized silkworm eggsVRCHOTOVÁ, Markéta January 2017 (has links)
Transgenesis of silkworms has great potential for the development of silk with new properties as well as for the preparation of recombinant proteins for the use in biomedicine. Zabelina et al. (2015a) showed that transgenesis of parthenogenetic silkworms facilitates the selection and maintenance of transgenic homozygotes with stabile transgene insertions. However, the efficiency of transgenesis was less than 2 % compared to 60 % in the standard, non-parthenogenetic silkworms. The purpose of the present research was to explore the cause of this difference. Since transgenesis is normally performed at 25 °C but in the parthenogenetic silkworms at 15 °C (3 days incubation at this temperature is part of the protocol for the induction of parthenogenetic development), we assumed that the eggs incubated at 15 °C might have been injected with the DNA construct at unsuitable time. The work was therefore focused on the rate of embryogenesis at 15 °C in the eggs treated in different ways. Intensive cleavage of the control eggs (strain K23) was observed at 12 h after oviposition at 25 °C and between 24 and 36 h at 15 °C. The transgenesis of parthenogenetic silkworms is also complicated by the embryonic diapause. In the current work, diapause was suppressed by implanting PK1 ovaries into the non-parthenogenetic male hosts K23. Parthenogenetic development was activated by the heat shock in the chorionated eggs dissected from the implants. No cleavage was detected at 12 h after the acti-vation and nearly complete blastoderm was found at 48 h. In respect to the course of cleavage at 15 °C, transgene injection 24 h after the activating heat shock can be recommended. The eggs from endogenous ovaries of the K23 females, which also contained the implants of the PK1 ovaries, acquired partial capacity of parthenogenesis. Low rate of embryogenesis was also found in the transgenic clone VTG1. Current results suggest that more research is needed to understand and possibly explore differences in the rate of silkworms exposed to different treatments.
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Energy metabolism and enzymatic activity in the Ips typographus in relation to diapause.ŠTEFKOVÁ, Kristýna January 2017 (has links)
The thesis describes the development and survival of immature Ips typographus specimens at low temperatures under laboratory and field conditions. Further, the focus was identifying and characterizing the digestive enzymes present in the gut of adult I. typographus, their location in the gut and enzymatic fluctuation over a full calendar year, with a specific focus on digestion of cellulose.
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CIRCADIAN GENES AND REGULATION OF DIAPAUSE IN INSECT / CIRCADIAN GENES AND REGULATION OF DIAPAUSE IN INSECTBAJGAR, Adam January 2013 (has links)
This thesis considers various roles of circadian clock genes in insect physiology. Application of molecular-biology methods in Pyrrhocoris apterus, non-model insect species, enable us to investigate involvement of circadian clock genes in photoperiod induced physiological responses. We discover involvement of neuroendocrine cells, and a role of Juvenile hormone (JH) signalization in transduction of photoperiodic signalization to peripheral tissues. We found new principles of JH signal diversification in tissue specific manner, and in addition described molecular mechanism of photoperiod induced changes in gut physiology. Comparison of gut and fat body tissue reveals that mechanism observed in the gut is tissue specific, and that circadian clock genes exhibit tissue specific functional pleiotropic effect.
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Molekulární a environmentální faktory spojené s diapauzou a stárnutím hmyzu / Molecular and environmental factors connected to diapause and aging in insectZDECHOVANOVÁ, Lenka January 2007 (has links)
Current models state that insect peripheral oscillators are directly responsive to light, while mammalian peripheral clock genes are coordinated by a master clock in the brain via intermediate factors, possibly hormonal. We show that the expression levels of two circadian clock genes, period (per) and Par Domain Protein 1 (Pdp1) in the peripheral tisue of an insect model species are inversely affected by contrasting photoperiods. The effect of photoperiod on per and Pdp1 mRNA levels was found to be mediated by the juvenile hormone. Our results provide the first experimental evidence for hormonal regulation of circadian clock gene expression in insects.
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Vliv eneregetických rezerv na úspěšnost přezimování a reprodukční potenciál lýkožrouta smrkového (\kur{Ips typographus} (L.)) / The energetic state of the spruce bark beetle (\kur{Ips typographus} (L.)): Implications for winter survivalBARTOŠOVÁ, Eva January 2010 (has links)
The thesis deals with characterisation and changes of energetic status in the spruce bark beetle, Ips typographus, during pre-diapause, diapause and post-diapause quiescence.
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