Gerald Franz

Conditional embryonic lethality to improve the sterile insect technique in Ceratitis capitata (Diptera: Tephritidae).

BackgroundThe sterile insect technique (SIT) is an environment-friendly method used in area-wide pest management of the Mediterranean fruit fly Ceratitis capitata (Wiedemann; Diptera: Tephritidae). Ionizing radiation used to generate reproductive sterility in the mass-reared populations before release leads to reduction of competitiveness.ResultsHere, we present a first alternative reproductive sterility system for medfly based on transgenic embryonic lethality. This system is dependent on newly isolated medfly promoter/enhancer elements of cellularization-specifically-expressed genes. These elements act differently in expression strength and their ability to drive lethal effector gene activation. Moreover, position effects strongly influence the efficiency of the system. Out of 60 combinations of driver and effector construct integrations, several lines resulted in larval and pupal lethality with one line showing complete embryonic lethality. This line was highly competitive to wildtype medfly in laboratory and field cage tests.ConclusionThe high competitiveness of the transgenic lines and the achieved 100% embryonic lethality causing reproductive sterility without the need of irradiation can improve the efficacy of operational medfly SIT programs.

Molecular and genetic analysis of an embryonic gene, DC 8, from Daucus carota L.

SummaryTo understand the morphogenetic and physiological processes occurring during plant embryogenesis, we isolated cDNA clones homologous to genes preferentially expressed during somatic embryogenesis. One of these cDNA clones detected an embryo-specific mRNA species with a corresponding protein of 66 kDa. The expression pattern of the mRNA is similar between somatic and zygotic embryos of carrots. To characterize the gene encoding this mRNA, we isolated the corresponding genomic clones. Molecular analysis of the DNA from several haploid and diploid carrots showed that the mRNA was encoded by a single copy gene, named DC 8. DNA sequence analysis showed that the gene consisted of three exons and coded for a hydrophilic protein with a central region composed of 17 repeats. At the NH2-terminus no typical signal sequence was found. Immunocytochemical analysis localized the protein primarily in the vacuoles and protein bodies of zygotic embryos; the cytoplasm showed some antibody staining. The protein was also found in cell walls of endosperm tissue. The amount of DC 8 protein was too low for it to be categorized as a seed storage protein; its role in embryogenesis remains to be determined.

Eukaryotic transposable element

Transposable elements first discovered in maize have been discovered subsequently also in bacteria, yeast,Drosophila, mammals etc. Structurally, eukaryotic transposable elements may be classified into two groups: ones with direct or inverse-repeat ends and the others with dAMP-rich sequence at one end. They generate direct repeats at the target site. Quite often, transposable elements are dispersed as a number of copies through the genome and at times may constitute a small but significant fraction. Their dispersal or transposition through the genome may involve excision (precise or imprecise), recombination (homologous or non-homologous) and replicative events in elements with direct or inverse repeats. dAMP-ended elements may move by reverse transcription. Maize elements can modulate gene action and yeast Tyl elements can enhance transcription. Nevertheless, evidence is not conclusive that transposable elements are involved in a major way in gene regulation and development. Structural similarities among yeast Tyl elements,Drosophila copia sequences and retroviral proviruses such as Rous sarcoma virus (RSV) and mouse mammary tumor virus (MMTV) suggest a formal possibility of horizontal transfers.

Incompatible insect technique: incompatible males from a Ceratitis capitata genetic sexing strain.

Wolbachia are obligatory intracellular and maternally inherited bacteria that infect and spread through natural arthropod populations by inducing male‐killing, feminization, parthenogenesis, and, most commonly, unidirectional and bidirectional cytoplasmic incompatibility (CI). Cytoplasmic incompatibility can be used to control natural populations of insect pests, in a way analogous to the Sterile Insect Technique (SIT), namely through the Incompatible Insect Technique (IIT). For the successful application of the IIT (based on a unidirectional CI approach) against a target species, it is essential that only males are released, as the release of females would lead to fertile matings between the released males and the released females and the establishment of a Wolbachia‐carrying field population. In the present study, we describe a Wolbachia‐infected line of the VIENNA 8 genetic sexing strain of the Mediterranean fruit fly, Ceratitis capitata (Wiedemann) (Diptera: Tephritidae), that carries the selectable marker temperature sensitive lethal (tsl). We show that (1) transferred Wolbachia induce high levels of CI even after the temperature treatment required for the male‐only production, and (2) the Wolbachia‐infected genetic sexing C. capitata line can be used in cage population suppression experiments analogous to the SIT. We also discuss our results in a comparison between IIT and SIT, investigating whether irradiation and cytoplasmic factors can be combined toward the development of novel strategies for insect pest control.

Recombination between homologous autosomes in medfly (Ceratitis capitata) males: type-1 recombination and the implications for the stability of genetic sexing strains

The sterile insect technique (SIT) is an environmentally safe technology to control insect pests. To improve this technology, genetic sexing strains (GSS) have been developed for the Mediterranean fruit fly, Ceratitis capitata. Such strains are based on Y-autosome translocations linking a selectable marker to the male sex and their long-term stability, especially under large-scale mass rearing conditions, is threatened by genetic recombination in the heterozygous males. We have measured male recombination in order to be able to construct GSS that are more stable. Our results show that male recombination occurs at very low frequencies, that is, below 1% per generation. Furthermore, recombination in medfly males occurs premeiotically. By selecting strains where the Y-autosome translocation breakpoint and the selectable marker are closely linked, the deleterious effects of recombination on the stability of GSS can be minimized. In such strains recombination is reduced by ca. 80% as compared to previously studied GSS. Although recombinants still occur at very low frequencies they still pose a threat to the integrity of the sexing system if they possess a selective advantage. Under mass rearing condition such recombinants will accumulate according to their relative fitness and additional measures, such as improved mass rearing strategies, are required to preserve the accuracy of the sexing system. As a conclusion it is shown that current GSS are stable enough to allow mass rearing at levels exceeding 1000 million male medflies per week.

Transcriptional regulation of a seed-specific carrot gene, DC8

Many late embryogenesis abundant (Lea) protein genes in plants are regulated by abscisic acid (ABA). The RNA level of a carrot gene, DC8, increases in response to ABA in developing seeds. However, DC8 cannot be induced by ABA in adult tissues. We used chimeric genes made of various DC8 promoter fragments fused to β-glucuronidase (GUS) to analyze the transcriptional regulation of DC8. DC8:GUS expression was measured in electroporated carrot protoplasts and in stably transformed carrots. The region of the DC8 promoter from −170 to −51 contained ABA-responsive sequences that required a 5′ upstream region for high levels of expression in embryogenic callus protoplasts. 505 bp of the DC8 promoter conferred GUS expression in stably transformed somatic and zygotic embryos. DC8:GUS was expressed only in tissues formed in the seed. This includes cells in the embryo, the endosperm and the germinating seedlings. Gel retardation and competition experiments were performed to analyze the embryo nuclear protein-DNA binding activities in vitro. No binding activity was detected on the putative ABA-responsive region; however the 5′ upstream regions located between -505 and -301 interacted with embryo nuclear factors. An additional site of DNA-protein interaction was located between positions -32 and +178. The nuclear proteins that bind these sequences were found in the embryo nuclei only, not in the nuclei from leaves or roots.

Molecular technologies to improve the effectiveness of the sterile insect technique

The application of the Sterile Insect Technique (SIT) in area-wide integrated pest management (AW-IPM) programmes continues to increase. However, programme efficiency can still be considerably enhanced when certain components of the technology are improved, such as the development of improved strains for mass rearing and release. These include strains that (1) produce only male insects for sterilization and release and (2) carry easily identifiable markers to identify released sterile insects in the field. Using both classical and modern biotechnology techniques, key insect pests are targeted, where SIT programmes are being implemented. The pests include mosquitoes, the Mexican fruit fly, the codling moth, the oriental fruit fly and the pink bollworm. This special issue summarizes the results of research efforts aimed at the development and evaluation of new strains to a level where a decision can be made as to their suitability for use in large scale SIT programmes. Major beneficiaries will be operational AW-IPM programmes that apply the SIT against major insect pests.

Development, genetic and cytogenetic analyses of genetic sexing strains of the Mexican fruit fly, Anastrepha ludens Loew (Diptera: Tephritidae)

BackgroundAnastrephaludens is among the pests that have a major impact on Méxicos economy because it attacks fruits as citrus and mangoes. The Mexican Federal government uses integrated pest management to control A. ludens through the Programa Nacional Moscas de la Fruta [National Fruit Fly Program, SAGARPA-SENASICA]. One of the main components of this program is the sterile insect technique (SIT), which is used to control field populations of the pest by releasing sterile flies.ResultsTo increase the efficiency of this technique, we have developed a genetic sexing strain (GSS) in which the sexing mechanism is based on a pupal colour dimorphism (brown-black) and is the result of a reciprocal translocation between the Y chromosome and the autosome bearing the black pupae (bp) locus. Ten strains producing wild-type (brown pupae) males and mutant (black pupae) females were isolated. Subsequent evaluations for several generations were performed in most of these strains. The translocation strain named Tapachula-7 showed minimal effect on survival and the best genetic stability of all ten strains. Genetic and cytogenetic analyses were performed using mitotic and polytene chromosomes and we succeeded to characterize the chromosomal structure of this reciprocal translocation and map the autosome breakpoint, despite the fact that the Y chromosome is not visible in polytene nuclei following standard staining.ConclusionsWe show that mitotic and polytene chromosomes can be used in cytogenetic analyses towards the development of genetic control methods in this pest species. The present work is the first report of the construction of GSS of Anastrepha ludens, with potential use in a future Moscafrut operational program.

Mitotic and polytene chromosomes analysis of the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae)

The Oriental fruit fly, Batrocera dorsalis s.s. (Hendel) is one of the most destructive agricultural pests, belonging to a large group of difficult to distinguish morphologically species, referred as the B. dorsalis complex. We report here a cytogenetic analysis of two laboratory strains of the species and provide a photographic polytene chromosome map from larval salivary glands. The mitotic complement consists of six chromosome pairs including a heteromorphic sex (XX/XY) chromosome pair. Analysis of the polytene complement has shown a total of five polytene chromosomes (10 polytene arms) that correspond to the five autosomes. The most important landmarks of each polytene chromosome and characteristic asynapsis at a specific chromosomal region are presented and discussed. Chromosomal homology between B. dorsalis and Ceratitis capitata has been determined by comparing chromosome banding patterns. The detection of chromosome inversions in both B. dorsalis strains is shown and discussed. Our results show that the polytene maps presented here are suitable for cytogenetic analysis of this species and can be used for comparative studies among species of the Tephritidae family. They also provide a diagnostic tool that could accelerate species identification within the B. dorsalis complex and could shed light on the ongoing speciation in this complex. Polytene chromosome maps can facilitate the development of biological control methods and support the genome mapping project of the species that is currently in progress.

The construction of the first balancer chromosome for the Mediterranean fruit fly, Ceratitis capitata.

Abstract The construction of the first balancer chromosome, FiM1, for the medfly Ceratitis capitata is described. This chromosome has three overlapping pericentric inversions and is marked with dominant and recessive mutations. The inversion breakpoints of FiM1 suppress recombination throughout the length of the fifth chromosome, allowing lethal mutations to be recovered and maintained. This chromosome will provide a powerful tool for the manipulation of laboratory stocks, in particular, the recovery of new mutant and transgenic strains. We demonstrate the use of FiM1 for the recovery and maintenance of chromosomes carrying lethal mutations.