Trojan Genes or Transparent Genomes? Sexual Selection and Potential Impacts of Genetically Modified Animals in Natural Ecosystems

Introgression of genetically engineered modifications (GMs) into natural populations represents a new realm for mutation theory. GMs, like mutations, have direct and pleiotropic impacts that can disrupt evolved adaptive suites. If GM males are more competitive or attractive mates, the “Trojan Gene Hypothesis” predicts potentially drastic impacts. We examined sexual selection in transgenic growth hormone (Tg) mice that are strong Trojan candidates given their exceptional size and extensive pleiotropic deficits. We hypothesized that the sophisticated olfactory abilities of females would recognize dysregulation of Tg males (the Transparent Genome Hypothesis). Females expressed interest in Tg males and their volatile scent, but when allowed nasal contact with urine (critical to mate choice) they preferred normal males. Tg male urine had reduced major urinary proteins (important in social signaling) and contained albumin and transferrin indicative of pathology. Novel Tg males failed to elicit pregnancy block in recently inseminated females (the “Bruce Effect”) whereas normal males were highly effective. Normal males expressed high aggression but Tg males were placid, non-aggressive and were largely ignored by normal males. Female mice also strongly preferred normal males over p53^± knockout males in response to volatiles, contact with urine and male presence. This study suggests that conspecific discrimination of fitness may be more powerful than generally appreciated. This has great implications for introductions of GM animals and sexual selection generally.     

Genetic modifiers of muscular dystrophy: implications for therapy

The genetic understanding of the muscular dystrophies has advanced considerably in the last two decades. Over 25 different individual genes are now known to produce muscular dystrophy, and many different "private" mutations have been described for each individual muscular dystrophy gene. For the more common forms of muscular dystrophy, phenotypic variability can be explained by precise mutations. However, for many genetic mutations, the presence of the identical mutation is associated with marked phenotypic range that affects muscle function as well as cardiac function. The explanation for phenotype variability in the muscular dystrophies is only now being explored. The availability of genetically engineered animal models has allowed the generation of single mutations on the background of highly inbred strain. Phenotypic variation that is altered by genetic background argues for the presence of genetic modifier loci that can ameliorate or enhance aspects of the dystrophic phenotype. A number of individual genes have been implicated as modifiers of muscular dystrophy by studies in genetically engineered mouse models of muscular dystrophy. The value of these genes and products is that the pathways identified through these experiments may be exploited for therapy.     

Safety assessment of leaf curl virus resistant tomato developed using viral derived sequences

Genetic engineering of food crops has significantly influenced the agricultural productivity over the past two decades. It has proved a valuable tool, offering crops with higher yields, improved nutritional quality, resistance against pesticides, herbicides and tolerance against abiotic stresses. However, the safety assessment of genetically engineered (GE) crops is prerequisite before introduction into human food chain. The present study was aimed to assess the toxicity and allergenicity of leaf curl virus resistant GE tomato compared to its wild-type species. Balb/c mice fed with genetically engineered or wild-type tomato did not show significant differences in growth, body weight (P > 0.05) and food consumption when compared with control mice. Values for serum glutamic oxaloacetic transaminase and serum glutamic pyruvic transaminase, urea and cholesterol were comparable in GE and wild-type tomato fed mice. Mice immunized with GE or wild-type tomato extract showed low IgE response. Lung histology of ovalbumin fed mice showed bronchoconstriction with eosinophilic infiltration whereas GE or wild-type tomato showed no cellular infiltration with normal airways. Genetically engineered and wild-type tomato sensitized mice demonstrated similar IL-4 release in splenic cell culture supernatant. GE and wild tomato extract on ELISA showed comparable IgE binding (P > 0.05) with food allergic patients’ sera. In conclusion, genetically engineered tomato showed no toxicity in mice and allergenicity is similar to the wild-type tomato.     

Use of the viral 2A peptide for bicistronic expression in transgenic mice

Background  

Transgenic animals are widely used in biomedical research and biotechnology. Multicistronic constructs, in which several proteins are encoded by a single messenger RNA, are commonly used in genetically engineered animals. This is currently done by using an internal ribosomal entry site to separate the different coding regions. 2A peptides result in the co-translational 'cleavage' of proteins and are an attractive alternative to the internal ribosomal entry site. They are more reliable than the internal ribosomal entry site and lead to expression of multiple cistrons at equimolar levels. They work in a wide variety of eukaryotic cells, but to date have not been demonstrated to function in transgenic mice in an inheritable manner.     

Folate modulates Hox gene-controlled skeletal phenotypes

Hox genes are well-known regulators of pattern formation and cell differentiation in the developing vertebrate skeleton. Although skeletal variations are not uncommon in humans few mutations in human HOX genes have been described. If such mutations are compatible with life, there may be physiological modifiers for the manifestation of Hox gene-controlled phenotypes, masking underlying mutations. Here we present evidence that the essential nutrient folate modulates genetically induced skeletal defects in Hoxd4 transgenic mice. We also show that chondrocytes require folate for growth and differentiation and that they express folate transport genes, providing evidence for a direct effect of folate on skeletal cells. To our knowledge, this is the first report of nutritional influence on Hox gene-controlled phenotypes, and implicates gene-environment interactions as important modifiers of Hox gene function. Taken together, our results demonstrate a beneficial effect of folate on skeletal development that may also be relevant to disorders and variations of the human skeleton.     

Genetic Background Effects on Disease Onset and Lifespan of the Mutant Dynactin p150Glued Mouse Model of Motor Neuron Disease

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease primarily affecting motor neurons in the central nervous system. Although most cases of ALS are sporadic, about 5–10% of cases are familial (FALS) with approximately 20% of FALS caused by mutations in the Cu/Zn superoxide dismutase (SOD1) gene. We have reported that hSOD1-G93A transgenic mice modeling this disease show a more severe phenotype when the transgene is bred on a pure SJL background and a milder phenotype when bred on a pure B6 background and that these phenotype differences link to a region on mouse Chromosome 17.To examine whether other models of motor neuron degeneration are affected by genetic background, we bred the mutant human dynactin p150^Glued (G59S-hDCTN1) transgene onto inbred SJL and B6 congenic lines. This model is based on an autosomal dominant lower motor neuron disease in humans linked to a mutation in the p150^Glued subunit of the dynactin complex. As seen in hSOD1-G93A mice, we observed a more severe phenotype with earlier disease onset (p<0.001) and decreased survival (p<0.00001) when the G59S-hDCTN1 transgene was bred onto the SJL background and delayed onset (p<0.0001) with increased survival (p<0.00001) when bred onto the B6 background. Furthermore, B6 mice with an SJL derived chromosome 17 interval previously shown to delay disease onset in hSOD1-G93A mice also showed delays onset in G59S-hDCTN1 mice suggesting that at least some genetic modifiers are shared. We have shown that genetic background influences phenotype in G59S-hDCTN1 mice, in part through a region of chromosome 17 similar to the G93-hSOD1 ALS mouse model. These results support the presence of genetic modifiers in both these models some of which may be shared. Identification of these modifiers will highlight intracellular pathways involved in motor neuron disease and provide new therapeutic targets that may be applicable to motor neuron degeneration.     

Modifier genes in mice and humans

An emerging theme of studies with spontaneous, engineered and induced mutant mice is that phenotypes often depend on genetic background, implying that genetic modifiers have a role in guiding the functional consequences of genetic variation. Understanding the molecular and cellular basis by which modifier genes exert their influence will provide insights into developmental and physiological pathways that are critical to fundamental biological processes, as well as into novel targets for therapeutic interventions in human diseases.     

猪生长激素基因表达质粒的构建及其转基因动物研究

将猪生长激素基因（ＰＧＨ）克隆到质粒ｐＵＣ１９上,经酶切分析,确定其酶切图谱．把ＰＧＨ转录起始位点以前的序列切掉,换上羊ＭＴ－１ａ基因的启动子,构建成可以调控的表达载体ｐＳＭＴＰＧＨ,用于转基因动物的研究．采用微注射法将线状ｐＳＭＴＰＧＨ导入猪、鼠和金鱼的受精卵中,得到了相应的转基因动物．对这些动物鉴定分析表明,外源基因整合率因动物不同而异,但该基因在这３种动物中的整合率均在９％以上,其生长速度都高于对照组．     

Genetic background modifies inner ear and eye phenotypes of jag1 heterozygous mice

Mice heterozygous for missense mutations of the Notch ligand Jagged1 (Jag1) exhibit head-shaking behavior indicative of an inner ear vestibular defect. In contrast, mice heterozygous for a targeted deletion of the Jag1 gene (Jag1del1) do not demonstrate obvious head-shaking behavior. To determine whether the differences in inner ear phenotypes were due to the types of Jag1 mutations or to differences in genetic background, we crossed Jag1del1 heterozygous mice onto the same genetic background as the missense mutants. This analysis revealed that variation of the Jag1 mutant inner ear phenotype is caused by genetic background differences and is not due to the type of Jag1 mutation. Genome scans of N2 backcross mice identified a significant modifier locus on chromosome 7, as well as a suggestive locus on chromosome 14. We also analyzed modifiers of an eye defect in Jag1del1 heterozygous mice from this same cross.     

X. Trefoil peptide and EGF receptor/ligand transgenic mice

The use of genetically engineered mice with both gain-of-function and loss-of-function mutations has been particularly informative about the normal and pathophysiological actions of a number of regulatory peptides of the gastrointestinal tract. This review highlights some of the major findings pertinent to the epidermal growth factor (EGF) receptor and its ligands, particularly the major gut ligand transforming growth factor-alpha, as well as the trefoil peptides. Both of these peptide families have important local actions in maintaining tissue homeostasis and repair after injury, and when mechanisms governing their regulation are disrupted they may contribute to disease progression. Future applications of transgenic technology to these areas are likely to be productive in furthering our understanding of the biology of these peptides in health and disease.     

Extending Serum Half-life of Albumin by Engineering Neonatal Fc Receptor (FcRn) Binding

A major challenge for the therapeutic use of many peptides and proteins is their short circulatory half-life. Albumin has an extended serum half-life of 3 weeks because of its size and FcRn-mediated recycling that prevents intracellular degradation, properties shared with IgG antibodies. Engineering the strictly pH-dependent IgG-FcRn interaction is known to extend IgG half-life. However, this principle has not been extensively explored for albumin. We have engineered human albumin by introducing single point mutations in the C-terminal end that generated a panel of variants with greatly improved affinities for FcRn. One variant (K573P) with 12-fold improved affinity showed extended serum half-life in normal mice, mice transgenic for human FcRn, and cynomolgus monkeys. Importantly, favorable binding to FcRn was maintained when a single-chain fragment variable antibody was genetically fused to either the N- or the C-terminal end. The engineered albumin variants may be attractive for improving the serum half-life of biopharmaceuticals.     

Chr 19A/J modifies tumor resistance in a sex- and parent-of-origin-specific manner

Neurofibromatosis type 1 (NF1) is one of the most common human genetic diseases affecting the nervous system and predisposes individuals to cancer, including peripheral nerve sheath tumors (PNSTs) and astrocytomas. Modifiers in the genetic background affect the severity of the disease and we have previously mapped two modifier loci, Nstr1 and Nstr2, that influence resistance to PNSTs in the Nf1−/+;Trp53−/+cis mouse model of NF1. We report here the analysis of Nstr1 in isolation from other epistatic loci using a chromosome substitution strain, and further show that a modifier locus (or loci) on chromosome 19 influences resistance to both PNSTs and astrocytomas. This modifier locus interacts with sex, resulting in sex-specific modification of tumors. Allele variability on chromosome 19 affects both the timing and the penetrance of the growth of different tumor types associated with NF1, specifically PNSTs and astrocytoma. These results indicate that modifiers of cancer susceptibility interact and affect tumorigenesis under different genetic conditions and demonstrate the power of chromosome substitution strains to study genetic modifiers. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Human umbilical cord blood cells transfected with VEGF and L(1)CAM do not differentiate into neurons but transform into vascular endothelial cells and secrete neuro-trophic factors to support neuro-genesis-a novel approach in stem cell therapy

Genetically modified mono-nuclear cell fraction from human umbilical cord blood (HUCB) expressing human vascular endothelial growth factor (VEGF) and mouse neural L₁ cell adhesion molecule (L₁CAM) were used for gene-stem cell therapy of transgenic ^G93^A mice adopted as an animal amyotrophic lateral sclerosis (ALS) model. We generated non-viral plasmid constructs, expressing human VEGF₁₆₅ (pcDNA-VEGF) and mouse neural L₁ cell adhesion molecule (pcDNA-mL₁CAM). Mono-nuclear fraction of HUCB cells were transiently transfected by electro-poration with a mixture of expression plasmids (pcDNA-VEGF + pcDNA-mL₁CAM). Sixteen transgenic female and male mice were randomly assigned to three groups: (1) transplantation of genetically modified HUCB cells expressing L₁ and VEGF (n = 6), (2) transplantation of un-transfected HUCB cells (n = 5), and (3) control group (n = 5). In first two experimental groups 1 × 10⁶ cells were injected retro-orbitally in pre-symptomatic 22–25-week-old ^G93^A mice. Our results demonstrate that HUCB cells successfully grafted into nervous tissue of ALS mice and survived for over 3 months. Therefore, genetically modified HUCB cells migrate in the spinal cord parenchyma, proliferate, but instead of transforming into nerve cells, they differentiate into endothelial cells forming new blood vessels. We propose that: (A) expression of mouse neural L₁CAM is responsible for increased homing and subsequent proliferation of transplanted cells at the site of neuro-degeneration, (B) expression of human VEGF directs HUCB cell differentiation into endothelial cells, and (C) neuro-protective effect may stem from the delivery of various neuro-trophic factors from newly formed blood vessels.     

Standing genetic variation and compensatory evolution in transgenic organisms: a growth-enhanced salmon simulation

Genetically modified strains usually are generated within defined genetic backgrounds to minimize variation for the engineered characteristic in order to facilitate basic research investigations or for commercial application. However, interactions between transgenes and genetic background have been documented in both model and commercial agricultural species, indicating that allelic variation at transgene-modifying loci are not uncommon in genomes. Engineered organisms that have the potential to allow entry of transgenes into natural populations may cause changes to ecosystems via the interaction of their specific phenotypes with ecosystem components and services. A transgene introgressing through natural populations is likely to encounter a range of natural genetic variation (among individuals or sub-populations) that could result in changes in phenotype, concomitant with effects on fitness and ecosystem consequences that differ from that seen in the progenitor transgenic strain. In the present study, using a growth hormone transgenic salmon example, we have modeled selection of modifier loci (single and multiple) in the presence of a transgene and have found that accounting for genetic background can significantly affect the persistence of transgenes in populations, potentially reducing or reversing a "Trojan gene" effect. Influences from altered life history characteristics (e.g., developmental timing, age of maturation) and compensatory demographic/ecosystem controls (e.g., density dependence) also were found to have a strong influence on transgene effects. Further, with the presence of a transgene in a population, genetic backgrounds were found to shift in non-transgenic individuals as well, an effect expected to direct phenotypes away from naturally selected optima. The present model has revealed the importance of understanding effects of selection for background genetics on the evolution of phenotypes in populations harbouring transgenes.     

Somatotropic and lactotropic receptors in transgenic mice expressing human or bovine growth hormone genes

The somatotropic and lactotropic receptors were studied in liver microsomal preparations from transgenic mice carrying the human growth hormone (hGH) or bovine growth hormone (bGH) gene fused to mouse metallothionein-I (MT) or phosphoenolpyruvate carboxykinase promoter/regulator (PEPCK). Specificity studies indicated that, similarly to normal mice, liver microsomes from the transgenic animals possess a mixed population of somatotropic and lactotropic binding sites. In transgenic animals of both sexes, the binding capacity of somatotropic receptors was significantly increased without corresponding changes in affinity. Expression of the MT-hGH hybrid gene was associated with the induction of somatotropic receptors which was approximately twice as great as that measured in animals expressing the MT-bGH hybrid gene. The binding capacity of lactotropic receptors in liver microsomes (quantitated, by the use, of labelled ovine prolactin) was increased 2–3 fold in transgenic females and approximately 10-fold in transgenic males as compared to the respective normal controls. We conclude that lifelong excess of GH up-regulates hepatic GH and prolactin receptors, and that lactogenic activity of GH is not essential for induction of prolactin receptors in the liver of transgenic mice.     

Pharmacokinetics of radioiodinated human and ovine growth hormones in transgenic mice expressing bovine growth hormone

Pharmacokinetics of radioiodinated human growth hormone (hGH) and ovine growth hormone (oGH) were studied in normal mice and in transgenic mice carrying the bovine growth hormone (bGH) gene fused to phosphoenolpyruvate carboxykinase promoter/regulator (PEPCK-bGH). Multiexponential plasma decay curves were obtained in both normal and transgenic mice after a¹²⁵I-oGH injection and pharmacokinetic parameters were estimated by fitting blood concentration data to a three compartment model. The half-life for the rapid compartment was shorter in transgenic than in normal mice (t_1/2:1.2±0.3 vs. 2.2±0.5 min). The slow compartment had a t_1/2 of 160±23 min for transgenic and 70±8 min for normal mice while the middle compartment had a t_1/2 of approximately 10 min for both groups of mice. The mean residence times were 167±24 and 55±5 min for transgenic and normal mice, respectively. Specific liver uptake of radioactivity after injection of¹²⁵I-oGH or¹²⁵I-hGH was found in both groups of animals. Specificity studies indicated that, similarly to normal mice, livers of transgenic mice possess a mixed population of somatotropic and lactogenic receptors. Uptake of labelled hGH by the liver was dose-dependent and the doses that prevented 50% of liver uptake (ED_50%) were 8 and 165 g per 50 g body weight for normal and transgenic mice, respectively. Thesein vivo results confirm and extend previousin vitro findings that a life-long excess of bGH increases hepatic somatotropic and lactogenic receptors. Since elevation in growth hormone (GH) receptors was reported to be associated with an increase in GH binding protein (GHBP), we suspect that both the increase in the mean residence time and the reduction in specific uptake of GH in the livers of transgenic mice may be the result of an increase in GHBP levels.     

Ovarian follicle apoptosis in bovine growth hormone transgenic mice

Growth hormone directly or via insulin like-growth factor-I has been shown to inhibit preovulatory follicle apoptosis, which is the underlying mechanism of follicular atresia. We studied the levels of apoptosis in the ovaries of transgenic mice expressing bovine growth hormone. Female bovine growth hormone transgenic mice (n = 10) and nontransgenic litter mates (n = 8) were killed at early proestrus. Ovaries were collected, sectioned, and processed using a nonradioactive in situ method for apoptosis detection. Follicles were classified and counted on the basis of size and level of apoptosis. Our results demonstrate that the percentage of ovarian follicles containing apoptotic cells was lower in transgenic versus normal mice (30% vs. 46%; P < 0.05). The percentage of follicles undergoing heavy apoptosis was lower (P < 0.05) in transgenic versus control animals in preovulatory and early antral follicles, but it was not different in preantral follicles. The percentage of healthy preovulatory follicles was also higher in transgenic versus normal mice (7.4% vs. 4.3%; P < 0.05). These results indicate that growth hormone overexpression in transgenic mice significantly decreases follicle apoptosis, and thus atresia in the mouse ovary, therefore leading to increased propensity for ovulation in these animals.     

Complementation of myosin null mutants in Dictyostelium discoideum by direct functional selection

The eukaryotic slime mold Dictyostelium discoideum contains a single conventional myosin heavy chain gene (mhcA). Cell lines in which this gene was deleted via homologous recombination have been previously reported. These myosin null cells were shown to be defective for cytokinesis and for sporogenesis. We demonstrate here that the cloned mhcA gene can be reintroduced into these cells by the use of a direct functional selection. This selection was imposed by demanding that cells be capable of growth in suspension. The resulting transformants appear normal for cytokinesis, and also are fully competent for sporogenesis, confirming that reintroduction of the myosin gene is sufficient to restore these properties. These results demonstrate a method for rescuing mutants in Dictyostelium which may be generally applicable for genetically created mutations as well as for mutations which have been engineered.