The Exact Timing of Microinjection of Parthenogenetic Silkworm Embryos Is Crucial for Their Successful Transgenesis.

The use of parthenogenetic silkworm (Bombyx mori) strains, which eliminate the problem of recombination, is a useful tool for maintaining transgenic clonal lines. The generation of genetically identical individuals is becoming an important tool in genetic engineering, allowing replication of an existing advantageous trait combination without the mixing that occurs during sexual reproduction. Thus, an animal with a particular genetic modification, such as the ability to produce transgenic proteins, can reproduce more rapidly than by natural mating. One obstacle to the widespread use of parthenogenesis in silkworm genetic engineering is the relatively low efficiency of downstream transgenesis techniques. In this work, we seek to optimize the use of transgenesis in conjunction with the production of parthenogenetic individuals. We found that a very important parameter for the introduction of foreign genes into a parthenogenetic strain is the precise timing of embryo microinjection. Our modification of the original method increased the efficiency of transgene injection as well as the survival rate of injected embryos. We also provide a detailed description of the methodological procedure including a graphical overview of the entire protocol.

Production of cloned transgenic silkworms by breeding non-diapausing parthenogenetic strains.

Clonal transgenic silkworms are useful for the functional analysis of insect genes and for the production of recombinant proteins. Such silkworms have previously been created using an existing ameiotic parthenogenetic strain. However, the process was labor intensive, and the efficiency of producing transgenic silkworms was very low. To overcome this issue, we developed a more convenient and efficient method by breeding non-diapausing parthenogenetic strains. The strains produced non-diapausing eggs only when the embryogenesis of the parent eggs was performed at low temperatures, which could then be used for injecting vector plasmids. This demonstrated that transgenic silkworms could be produced with greater ease and efficiency. To breed the strains, we crossed the existing parthenogenetic strains with bivoltine strains and made F1 and F2 from each cross. Then we selected the silkworms whose eggs have a high ability of parthenogenesis and became non-diapausing. We also demonstrated that the germplasm could be cryopreserved in liquid nitrogen. Thus, this method increases the efficiency and ease of using genetically engineered silkworms to analyze gene function and produce recombinant proteins, potentially impacting various industries.

Genome engineering and parthenocloning in the silkworm, Bombyx mori.

Genetic engineering of the silkworm, Bombyx mori, opens door to the production of new kinds of silk and to the use of silkworms as proteosynthetic bioreactors. The insertion of foreign genes into silkworm genome and the control of their expression by diverse promoters have become possible but are not yet efficient enough for commercial use. Several methods of gene targeting are being developed to minimize position effect on transgene expression and facilitate cloning. Parthenocloning can be exploited to conserve genetic traits and improve selection and amplification of clones containing genes of interest. Some silkworm clones have been bred for decades as genetically stable female stocks whose unfertilized eggs are induced to develop by heat-shock treatment. Any exclusively female generation contains exact copies of the maternal clone-founder genome. Ovaries transplanted in either direction between the standard and the parthenogenetic genotypes yield eggs capable of parthenocloning. In addition, use ofmale larvae as ovary recipients eliminates diapause in eggs produced in the implants. Unfertilized eggs of some silkworm clones respond also to the cold-shock treatment by producing homozygous fertile sons; cloned females can be crossed with their parthenogenetic sons to obtain progeny homozygous for the transgene in both sexes. Rational exploitation of available parthenozygous pools and the use of parthenocloning methods enable rapid fixation and maintenance of the desired genotypes.

Construction and long term preservation of clonal transgenic silkworms using a parthenogenetic strain.

For the functional analysis of insect genes as well as for the production of recombinant proteins for biomedical use, clonal transgenic silkworms are very useful. We examined if they could be produced in the parthenogenetic strain that had been maintained for more than 40years as a female line in which embryogenesis is induced with nearly 100% efficiency by a heat shock treatment of unfertilized eggs. All individuals have identical female genotype. Silkworm transgenesis requires injection of the DNA constructs into the non-diapausing eggs at the preblastodermal stage of embryogenesis. Since our parthenogenetic silkworms produce diapausing eggs, diapause programing was eliminated by incubating ovaries of the parthenogenetic strain in standard male larvae. Chorionated eggs were dissected from the implants, activated by the heat shock treatment and injected with the transgene construct. Several transgenic individuals occurred in the daughter generation. Southern blotting analysis of two randomly chosen transgenic lines VTG1 and VTG14 revealed multiple transgene insertions. Insertions found in the parental females were transferred to the next generation without any changes in their sites and copy numbers, suggesting that transgenic silkworms can be maintained as clonal strains with homozygous transgenes. Cryopreservation was developed for the storage of precious genotypes. As shown for the VTG1 and VTG14 lines, larval ovaries can be stored in DMSO at the temperature of liquid nitrogen, transferred to Grace's medium during defrosting, and then implanted into larvae of either sex of the standard silkworm strains C146 and w1-pnd. Chorionated eggs, which developed in the implants, were dissected and activated by the heat shock to obtain females (nearly 100% efficiency) or by a cold shock to induce development to both sexes in 4% of the eggs. It was then possible to establish bisexual lines homozygous for the transgene.

Chromosome numbers for three species of medicinal leeches (Hirudo spp.).

Karyological preparations were made from the testisacs of three medicinal leech species Hirudo medicinalis Linnaeus, 1758, H. verbana Carena, 1820 and H. orientalis Utevsky & Trontelj, 2005 . The samples originated from different populations in Azerbaijan, Kazakhstan, Russian Federation, Ukraine and Uzbekistan. The chromosome numbers were determined both from mitotic and meiotic stages of spermatogenesis using the propionic haematoxylin staining technique. All three species were found to have different haploid chromosome numbers: H. medicinalis 14, H. verbana 13 and H. orientalis 12, thus corroborating the validity of these taxa. The chromosomes can be classified as meta-, submetacentric and acrocentric. The chromosome numbers obtained are similar to that of the related species Haemopis sanguisuga (Linnaeus, 1758), which has 13 pairs.