Rescuing lethal phenotypes induced by disruption of genes in mice: a review of novel strategies.

Approximately 35 % of the mouse genes are indispensable for life, thus, global knock-out (KO) of those genes may result in embryonic or early postnatal lethality due to developmental abnormalities. Several KO mouse lines are valuable human disease models, but viable homozygous mutant mice are frequently required to mirror most symptoms of a human disease. The site-specific gene editing systems, the transcription activator-like effector nucleases (TALENs), Zinc-finger nucleases (ZFNs) and the clustered regularly interspaced short palindrome repeat-associated Cas9 nuclease (CRISPR/Cas9) made the generation of KO mice more efficient than before, but the homozygous lethality is still an undesired side-effect in case of many genes. The literature search was conducted using PubMed and Web of Science databases until June 30th, 2020. The following terms were combined to find relevant studies: "lethality", "mice", "knock-out", "deficient", "embryonic", "perinatal", "rescue". Additional manual search was also performed to find the related human diseases in the Online Mendelian Inheritance in Man (OMIM) database and to check the citations of the selected studies for rescuing methods. In this review, the possible solutions for rescuing human disease-relevant homozygous KO mice lethal phenotypes were summarized.

GFP transgenic animals in biomedical research: a review of potential disadvantages.

Green Fluorescent protein (GFP) transgenic animals are accepted tools for studying various physiological processes, including organ development and cell migration. However, several in vivo studies claimed that GFP may impair transgenic animals' health. Glomerulosclerosis was observed in transgenic mice and rabbits with ubiquitous reporter protein expression. Heart-specific GFP expression evoked dilated cardiomyopathy and altered cardiac function in transgenic mouse and zebrafish lines, respectively. Moreover, growth retardation and increased axon swelling were observed in GFP and yellow fluorescent protein (YFP) transgenic mice, respectively. This review will focus on the potential drawbacks of the applications of GFP transgenic animals in biomedical research.

Monitoring of Venus transgenic cell migration during pregnancy in non-transgenic rabbits.

Cell transfer between mother and fetus were demonstrated previously in several species which possess haemochorial placenta (e.g. in humans, mice, rats, etc.). Here we report the assessment of fetal and maternal microchimerism in non-transgenic (non-TG) New Zealand white rabbits which were pregnant with transgenic (TG) fetuses and in non-TG newborns of TG does. The TG construct, including the Venus fluorophore cDNA driven by a ubiquitous cytomegalovirus enhancer, chicken ß-actin promoter (CAGGS), was previously integrated into the rabbit genome by Sleeping Beauty transposon system. Three different methods [fluorescence microscopy, flow cytometry and quantitative polymerase chain reaction (QPCR)] were employed to search for TG cells and gene products in blood and other tissues of non-TG rabbits. Venus positive peripheral blood mononuclear cells (PBMCs) were not detected in the blood of non-TG littermates or non-TG does by flow cytometry. Tissue samples (liver, kidney, skeletal and heart muscle) also proved to be Venus negative examined with fluorescence microscopy, while histology sections and PBMCs of TG rabbits showed robust Venus protein expression. In case of genomic DNA (gDNA) sourced from tissue samples of non-TG rabbits, CAGGS promoter-specific fragments could not be amplified by QPCR. Our data showed the lack of detectable cell transfer between TG and non-TG rabbits during gestation.

The potential impact of new generation transgenic methods on creating rabbit models of cardiac diseases.

Since the creation of the first transgenic rabbit thirty years ago, pronuclear microinjection remained the single applied method and resulted in numerous important rabbit models of human diseases, including cardiac deficiencies, albeit with low efficiency. For additive transgenesis a novel transposon mediated method, e.g., the Sleeping Beauty transgenesis, increased the efficiency, and its application to create cardiac disease models is expected in the near future. The targeted genome engineering nuclease family, e.g., the zink finger nuclease (ZFN), the transcription activator-like effector nuclease (TALEN) and the newest, clustered regularly interspaced short palindromic repeats (CRISPR) with the CRISPR associated effector protein (CAS), revolutionized the non-mouse transgenesis. The latest gene-targeting technology, the CRISPR/CAS system, was proven to be efficient in rabbit to create multi-gene knockout models. In the future, the number of tailor-made rabbit models produced with one of the above mentioned methods is expected to exponentially increase and to provide adequate models of heart diseases.

On the emerging role of rabbit as human disease model and the instrumental role of novel transgenic tools.

The laboratory rabbit (Oryctolagus cuniculus) is widely used as a model for human diseases, because of its size, which permits non-lethal monitoring of physiological changes and similar disease characteristics. Novel transgenic tools such as, the zinc finger nuclease method and the sleeping beauty transposon mediated or BAC transgenesis were recently adapted to the laboratory rabbit and opened new opportunities in precise tissue and developmental stage specific gene expression/silencing, coupled with increased transgenic efficiencies. Many facets of human development and diseases cannot be investigated in rodents. This is especially true for early prenatal development, its long-lasting effects on health and complex disorders, and some economically important diseases such as atherosclerosis or cardiovascular diseases. The first transgenic rabbits models of arrhythmogenesis mimic human cardiac diseases much better than transgenic mice and hereby underline the importance of non-mouse models. Another emerging field is epigenetic reprogramming and pathogenic mechanisms in diabetic pregnancy, where rabbit models are indispensable. Beyond that rabbit is used for decades as major source of polyclonal antibodies and recently in monoclonal antibody production. Alteration of its genome to increase the efficiency and value of the antibodies by humanization of the immunoglobulin genes, or by increasing the expression of a special receptor (Fc receptor) that augments humoral immune response is a current demand.

Transgenic rabbit production with simian immunodeficiency virus-derived lentiviral vector.

Transgenic rabbit is the preferred disease model of atherosclerosis, lipoprotein metabolism and cardiovascular diseases since upon introducing genetic mutations of human genes, rabbit models reflect human physiological and pathological states more accurately than mouse models. Beyond that, transgenic rabbits are also used as bioreactors to produce pharmaceutical proteins in their milk. Since in the laboratory rabbit the conventional transgenesis has worked with the same low efficiency in the last twenty five years and truly pluripotent embryonic stem cells are not available to perform targeted mutagenesis, our aim was to adapt lentiviral transgenesis to this species. A simian immunodeficiency virus based replication defective lentiviral vector was used to create transgenic rabbit through perivitelline space injection of fertilized oocytes. The enhanced green fluorescent protein (GFP) gene was placed under the ubiquitous CAG promoter. Transgenic founder rabbits showed mosaic pattern of GFP expression. Transgene integration and expression was revealed in tissues derived from all three primary germ layers. Transgene expression was detected in the developing sperm cells and could get through the germ line without epigenetic silencing, albeit with very low frequency. Our data show for the first time, that lentiviral transgenesis could be a feasible and viable alternative method to create genetically modified laboratory rabbit.

Humoral serotonin and dopamine modulate the feeding in the snail, Helix pomatia.

We investigated the effect of elevated levels of humoral 5HT and DA on the feeding latency of Helix pomatia, 1 day, 3 days and 10 days following satiation, by injecting monoamines into the haemocoel. HPLC assay of monoamines showed that both 5HT and DA are present in pmol/ml concentrations in the haemolymph of both starved and non-starved animals. Elevated levels of 5HT and DA were most effective at decreasing the feeding latency 10 days following satiation when DA decreased the feeding latency in a concentration dependent manner between 10(-7) and 10(-5) M whereas 5HT levels decreased the feeding latency only at 10(-6) M but increased it at 10(-5) M. Immunocytochemistry revealed that both 5HT3 and D1 receptor-like immuno-reactivity are present in cell bodies located in the same areas of the buccal ganglia. Our observations suggest that both humoral DA and 5HT mutually modulate the activity of the feeding CPG through neurons which have these receptors.

The terrestrial snail, Helix pomatia, adapts to environmental conditions by the modulation of central arousal.

The osmotic stimulation which is able to change the behavioral state of the animal are most effective during rainy weather while they are less effective during dry weather conditions. In isolated CNS preparations from aestivated animals the highest firing activity and serotonin sensitivity of the serotonergic (RPas) heart modulator neurons are recorded during rainy weather and the lowest parameters are observed in dry conditions. In aestivated animals the serotonin (5HT) content in both the CNS and the foot is higher than the dopamine (DA) content during rainy weather, while in dry weather the DA level is higher than the 5HT. The inactivation-reactivation process is accompanied by decreasing both the DA and 5HT levels in the CNS and increasing them in the peripheral organs. Our results suggest that aestivated animals adapt to (favorable and unfavorable) environmental conditions by modulating their central arousal state through changing the levels and distribution of monoamines (5HT, DA) in their body.

Neuronal background of activation of estivated snails, with special attention to the monoaminergic system: a biochemical, physiological, and neuroanatomical study.

Osmotic stimulation activates both estivated and inactivated specimens of Helix pomatia and increases their central arousal. High-pressure liquid chromatography has shown that, during activation, the level of both serotonin and dopamine decreases in the central nervous system (CNS) but increases in the foot and heart, organs that are involved in the eversion of the body. In isolated CNS from activated animals, the firing frequency of the heart-modulator serotonergic (RPas) neurons is significantly higher than that in the CNS of estivated or inactivated animals. These neurons innervate both the heart and the anterior aorta. In semi-intact preparations, distilled water (an osmotic stimulus) applied to the mantle collar increases their firing frequency, whereas tactile stimulation evokes their inhibition. Extracellularly applied monoamines mimic the effect of peripheral stimuli: serotonin (0.1-10 microM) increases the activity of the RPas neurons, whereas dopamine (0.1-10 microM) inhibits their activity. Tyrosine-hydroxylase immunocytochemistry and retrograde neurobiotin tracing have revealed similar bipolar receptor cells in the mantle collar and tail, organs that are exposed to environmental stimuli in estivated animals. Serotonin immunocytochemistry carried out on the same tissues does not visualize receptor cells but labels a dense network of fibers that appear to innervate neurobiotin-labeled receptor cells. The combination of neurobiotin-labeling of RPas neurons and immunolabeling suggests that RPas neurons receive direct dopaminergic inputs from receptor cells and serotonergic inputs from central serotonergic neurons, indicating that central serotonergic neurons are interconnected. Thus, the RPas neurons may belong to neuronal elements of the arousal system.

Thee effect of food intake on the central monoaminergic system in the snail, Lymnaea stagnalis.

We investigated the effect of food intake on the serotonin and dopamine levels of the CNS as well as on the spontaneous firing activity of the CGC in isolated preparations from starved, feeding and satiated animals. Furthermore we investigated the effects of 1 microM serotonin and/or dopamine and their mixture on the firing activity of the CGC. The HPLC assay of serotonin and dopamine showed that during food intake both the serotonin and dopamine levels of the CNS increased whereas in satiated animals their levels were not significantly more than the control levels. Recording from the CGC in isolated CNS preparation from starved, feeding or satiated animals showed that feeding increased the firing frequency of the CGC compared to the starved control. The application of 1 microM dopamine decreased the firing frequency whereas the application of 1 microM serotonin increased the firing frequency of the CGC. We conclude that during food intake the external and internal food stimuli increase the activity of the central monoaminergic system and also increase the levels of monoamines in the CNS. Furthermore, we also suggest that the increased dopamine and serotonin levels both affect the activity of the serotonergic neurons during the different phases of feeding.

Serotonergic and dopaminergic influence of the duration of embryogenesis and intracapsular locomotion of Lymnaea stagnalis L.

The role of the dopaminergic and serotonergic system was studied during the embryonic development of the pond snail Lymnaea stagnalis, with special attention to the effect of dopamine and serotonin as well as their agonists and antagonists on the rotation of the veliger larvae, and to the effect of precursors and inhibitors of the synthetizing enzymes on the duration of the embryonic life. Serotonin, D-lysergic acid diethylamide and N,N-dimethyltryptamine increased at a concentration of 1 microM the rotation by 50%, 90% and 87% respectively, and among them D-Lysergic acid diethylamide was found to be the most potent agonist. Other serotonergic agonists and antagonists enhanced the frequency of the rotation (from 165% to 355%) at higher threshold concentrations in the following rank order: methysergid > tryptamine > 2,5-dimethoxy-4-iodoamphetamine > 5-carboxyamidotryptamine > bromo-lysergic acid diethylamide > 7-methyltryptamine. Application of 1-(2-methoxyphenyl) piperazine decreased the rotation by 76%. The reuptake inhibitor desipramine completely blocked the rotation and killed the embryos. Dopaminergic agonists accelerated the rotation by 62% to 233%, and their effect was ranged as follows: dopamine > apomorphine > m-tyramine approximately equal to p-tyramine. Chlorpromazine at 100 microM concentration killed the embryos. At a concentration of 100 microg/ml, tyrosine, the precursor of DA, slowed down the embryonic development by increasing the duration of the embryonic life from 8 to 10 days. Decarboxylase inhibitors, alpha-methyl-3,4-dihydroxyphenyl-alanine (25 microg/ml) and m-hydroxybenzylhydrazin (5 microg/ml), killed 50% of the embryos, meanwhile the rest hatched ten days later, compared to the control animals. The development was partially blocked by the serotonin precusor L-tryptophane (50 microg/ml). Trytophan hydroxylase blocker, p-chlorphenylalanine (50 microg/ml) resulted in a distortion of the body pattern of the embryos, and prevented the hatching of most (95%) of the animals.

On the use of post-transcriptional processing elements in transgenes.

RNA processing events modulate final productivity of a given transgene. We have evaluated a series of RNA elements for their ability to enhance alpha1-antitrypsin production in mammary cells. Our results indicate the need for a case-by-case assessment of each construct design and the occurrence of gene silencing events in vivo.

The transgenic rabbit as model for human diseases and as a source of biologically active recombinant proteins.

Until recently, transgenic rabbits were produced exclusively by pronuclear microinjection which results in additive random insertional transgenesis; however, progress in somatic cell cloning based on nuclear transfer will soon make it possible to produce rabbits with modifications to specific genes by the combination of homologous recombination and subsequent prescreening of nuclear donor cells. Transgenic rabbits have been found to be excellent animal models for inherited and acquired human diseases including hypertrophic cardiomyopathy, perturbed lipoprotein metabolism and atherosclerosis. Transgenic rabbits have also proved to be suitable bioreactors for the production of recombinant protein both on an experimental and a commercial scale. This review summarizes recent research based on the transgenic rabbit model.

Dopamine and serotonin receptors mediating contractions of the snail, Helix pomatia, salivary duct.

The combination of high performance liquid chromatography, bioassay and immunocytochemistry was applied to study the regulation of the salivary duct muscle of the snail, Helix pomatia. The major function of the duct appears to be to propel the saliva toward the buccal cavity during feeding. It has been established that serotonin and dopamine applied exogenously mimic the effect on the duct exerted by the stimulation of the salivary nerve. Immunohistochemistry revealed the presence of serotonin, but not dopaminergic nerve elements in the nerve and along the duct surface. However, both serotonin (14.9-15.5 pmol/mg) and dopamine (0.38-0.58 pmol/mg), as well as the synthesizing enzymes (tyrozine hydroxylase 0.28 pmol/mg tissue/h and DOPA 0.32 nmol synthesized DA/mg tissue/h) could regularly be assayed in the salivary duct by high performance liquid chromatography. When released following the stimulation of the salivary nerve, both monoamines were shown to interact with distinct membrane receptors. Dopamine elicited a sustained increase of the muscle tone in concentration-dependent manner (K(d)=1.5 microM). Mammalian D(1) receptor antagonist flupenthixol and fluphenazine attenuated, whereas the D(1) receptor agonist SKF-38393 mimicked the effect elicited by exogenous dopamine. Serotonin had a double effect on the salivary duct: a relaxing and a contracting one with different K(d) values 76 nM and 2.4 microM, respectively. 5-HT(2) receptor antagonist ritanserin and ketanserin attenuated the serotonin-induced relaxation. In contrast 5-HT(3) antagonist metoclopramide and MDL2222 decreased and 5-HT(3) receptor agonist 1-(m-chlorophenyl)-biguanide mimicked the serotonin-induced contraction, suggesting that serotonin exerted its action on two different receptor subtypes. The release of radiolabeled serotonin and dopamine upon nerve stimulation was found to be Ca-dependent. Furthermore, the increase in serotonin concentration induced a decrease of the potency of dopamine to elicit sustained contraction. These results provide evidence for the transmitter role of serotonin and dopamine in salivary duct. It is concluded that receptors reveal a pharmacological profile related to vertebrate D(1), 5-HT(2) and 5-HT(3) receptor subtypes. Moreover, it was found that the process of conveying the saliva is modulated by an interaction of dopamine and serotonin.

Expression of active human blood clotting factor VIII in mammary gland of transgenic rabbits.

Human clotting factor VIII is probably the largest protein to be expressed to date in the mammary gland of a transgenic animal, and it requires extensive posttranslational modification to achieve full biological activity. The mammary gland specific construct mWAP-hFVIII-MT-I was injected into the pronuclei of rabbit zygotes, and three transgenic offspring were obtained. Founder 385 showed germ-line transmission of a single integrated copy, and a homozygous line was established from this animal. The rhFVIII was transcribed and translated exclusively in the mammary gland. The activity of rhFVIII in the rabbit milk ranged from 5 to 8% of that found in normal human plasma. Results indicate the suitability of the transgenic rabbit mammary gland for rhFVIII production.

Role of tyrosine, DOPA and decarboxylase enzymes in the synthesis of monoamines in the brain of the locust.

The metabolic transformation of tyrosine (TYR) by the decarboxylase and hydroxylase enzymes was investigated in the central nervous system of the locust, Locusta migratoria. It has been demonstrated that the key amino acids, 3,4-dihydroxyphenylalanine (DOPA), 5-hydroxytryptophan (5HTP) and tyrosine are decarboxylated in all part of central nervous system. DOPA and 5HTP decarboxylase activities show parallel changes in the different ganglia, but the rank order of the activity of TYR decarboxylase is different. Enzyme purification has revealed that the molecular weights of TYR decarboxylase and DOPA/5HTP decarboxylase are 370,000 and 112,000, respectively. The decarboxylation of DOPA by DOPA/5HTP decarboxylase is stimulated, whereas the decarboxylation of DOPA by TYR decarboxylase is inhibited in the presence of the cofactor pyridoxal-5'-phosphate. TYR hydroxylase could not be detected and 3H-TYR is found to be metabolised to tyramine (TA), but not to DOPA. The haemolymph contains a significant concentration of DOPA (120 pmol/100 microl haemolymph), and the ganglia incorporates DOPA from the haemolymph by a high affinity uptake process (K(M)=12 microM and V(max)=24 pmol per ganglion/10 min). Our results suggest that no tyrosine hydroxylase is present in the locust CNS and the DOPA uptake into the ganglia by a high affinity uptake process as well as the DOPA decarboxylase enzyme may be responsible for the regulation of the ganglionic dopamine (DA) level. Two types of decarboxylases exist, one of them decarboxylating DOPA and 5HTP (DOPA/5HTP decarboxylase), other decarboxylating TYR (TYR decarboxylase). The DOPA/5HTP decarboxylase enzyme present in the insect brain may correspond to the 5HTP/DOPA decarboxylase in vertebrate brain, whereas TYR decarboxylase is characteristic only for the insect brain.

Membrane effects of toxins isolated from a cyanobacterium, Cylindrospermopsis raciborskii, on identified molluscan neurones.

The effect of anatoxin (ANTX), the crude extract (AlgTX) and purified fraction (F1) isolated from cyanobacterium C. raciborskii was studied on the neurones of two snail species. ANTX and AlgTX exerted excitatory, inhibitory and biphasic effects on the spontaneous activity of identified neurones. Both ANTX and AlgTX elicited an inward current, which could be decreased by curare or amiloride. On the contrary, F1 had no direct effect on the spontaneous activity; it was not able to induce conductance changes of the neuronal membrane, but it did antagonise the acetylcholine (ACh)-induced inward current. We concluded that ANTX affects the neuronal membrane of neurones acting on ACh receptors. The AlgTX had similar effects, and therefore the extract of C. raciborskii may contain an ANTX-like component. The purified fraction prolonged and decreased the ACh-elicited response, but had no direct membrane effect. We suggest, therefore, that both AlgTX and the purified fraction F1 interact with the ACh receptor, but they have different binding sites on the neuronal ACh receptor-ion channel complex. The possible neurotoxic effects of the C. raciborskii extract and F1 are demonstrated for the first time; the molecular mechanism of their action, however, remains to be elucidated.

Stage-and tissue-specific expression of a Col2a1-Cre fusion gene in transgenic mice.

To achieve chondrocyte-specific deletion of floxed genes we generated a transgenic mouse line expressing the Cre recombinase under the control of the mouse type II collagen gene (Col2a1) regulatory regions. Northern and in situ hybridization analyses demonstrated the expression of the transgene (Col2a1-Cre) in cartilaginous tissues. To test the excision efficiency of Cre, the Col2a1-Cre strain was crossed with the ROSA26 reporter strain. LacZ staining of double transgenic mice revealed Cre activity in both chondrogenic and non-chondrogenic tissues. During early embryonic development (E9.5-11.5), LacZ expression was detected in tissues where the endogenous Col2a1 transcript is expressed such as the otic capsule, notochord, developing brain, sclerotome and mesenchymal condensations of future cartilage. At later stages, Cre activity was observed in all cartilaginous tissues with virtually 100% of chondrocytes being LacZ positive. These data suggest that the Col2a1-Cre mouse strain described here can be useful to achieve Cre-mediated recombination in Col2a1 expressing cells, especially in chondrocytes.

The possible roles of the monoaminergic system in the feeding of the snail Helix pomatia.

The possible role of serotonin and dopamine in the feeding of Helix pomatia was studied applying immunocytochemical, biochemical, and behavioral techniques as well as bioassay experiments. Immunocytochemistry showed that dopamine-containing (thyrosin-hydroxylase-immunoreactive) neuronal elements of the crop and the gizzard belong to the intrinsic part, whereas serotonin-containing (serotonin-immunoreactive) neuronal elements belong to the extrinsic part of the gastrointestinal nervous system. Bioassay studies on the spontaneous contractions of the crop and the gizzard showed that dopamine affected only the longitudinal muscle contractions by increasing both the tonus and contractility, whereas serotonin was effective on both the longitudinal and circular muscle contractions. Serotonin increased the tonus and contractility of longitudinal muscles in the crop but decreased them in the gizzard. Serotonin decreased the tonus and contractility of the circular muscles in the crop but increased them in the gizzard. Serotonin effects on the circular muscle of the gizzard were concentration dependent between a range of 10(-5) M-3 x 10(-5) M. HPLC measurements of monoamines in starved and satiated animals showed that the concentration of both dopamine and serotonin significantly decreased in both the CNS and different parts of the gastrointestinal tract of satiated animals, suggesting a significant monoamine liberation during feeding. The injection of monoamines (10(-3) and 10(-2) M) into the body cavity of starved animals showed that only dopamine was able to induce feeding whereas serotonin increased the general activity of the animals suggesting that the initiation of feeding is rather dopamine than serotonin dependent.

Octopamine is the synaptic transmitter between identified neurons in the buccal feeding network of the pond snail lymnaea stagnalis.

We report the pharmacological properties of synaptic connections from the three octopamine-containing OC interneurons to identified buccal feeding neurons in the pond snail, Lymnaea stagnalis. Intracellular stimulation of an OC interneuron evokes inhibitory postsynaptic potentials in the B3 motoneurons and N2 (d) interneurons, while the synapse between OC and N3 (phasic) interneurons has two components: an initial electrical excitation followed by chemical inhibition. All synaptic responses persist in a saline with elevated calcium and magnesium suggesting that the connections are monosynaptic. Local perfusion of 10(-4) M octopamine produces the same inhibitory membrane responses from these buccal neurons as OC stimulation. These responses also persist in high Mg(2+)/Ca(2+) saline indicating direct membrane effects. The similarities in reversal potentials for the synaptic hyperpolarization evoked on B3 neurons after OC stimulation (-89.0 mV, S.E.M.=14.1, n=10) and the octopamine response of the B3 neurons (-84.7 mV, S.E.M.=6.6, n=6) indicate that increased K(+)-conductance underlies both responses. Bath application of the octopaminergic drugs phentolamine (10(-6) M), epinastine (10(-6) M) or DCDM (10(-4) M) blocks the inhibitory synapse onto B3 or N2 neurons and the chemical component of the N3 response. They also block the octopamine-evoked inhibition of B3, N2 and N3 neurons. NC-7 (2x10(-5) M) has a hyperpolarizing agonist effect (like octopamine) on these neurons and also blocks their chemical synaptic input from the OC interneurons. These results provide pharmacological evidence that the neurotransmitter between the octopamine-immunopositive OC interneurons and its followers is octopamine. This is the first example of identified octopaminergic synaptic connections within the snail CNS.