The loss of DHX15 impairs endothelial energy metabolism, lymphatic drainage and tumor metastasis in mice.

DHX15 is a downstream substrate for Akt1, which is involved in key cellular processes affecting vascular biology. Here, we explored the vascular regulatory function of DHX15. Homozygous DHX15 gene deficiency was lethal in mouse and zebrafish embryos. DHX15-/- zebrafish also showed downregulation of VEGF-C and reduced formation of lymphatic structures during development. DHX15+/- mice depicted lower vascular density and impaired lymphatic function postnatally. RNAseq and proteome analysis of DHX15 silenced endothelial cells revealed differential expression of genes involved in the metabolism of ATP biosynthesis. The validation of these results demonstrated a lower activity of the Complex I in the mitochondrial membrane of endothelial cells, resulting in lower intracellular ATP production and lower oxygen consumption. After injection of syngeneic LLC1 tumor cells, DHX15+/- mice showed partially inhibited primary tumor growth and reduced lung metastasis. Our results revealed an important role of DHX15 in vascular physiology and pave a new way to explore its potential use as a therapeutical target for metastasis treatment.

Phytoestrogen-containing diets offer benefits for mouse embryology but lead to fewer offspring being produced.

One of the most commonly used protein sources in rodent diets is soy, which is naturally rich in phytoestrogens. Although phytoestrogens have shown potential health benefits in humans, they may also have the ability to disrupt reproduction. Consequently, there has been a tendency to try to exclude them from rodent diets. In the current study, we investigated whether phytoestrogen content in the mouse diet could affect reproduction in mice used as embryo donors. Donor mice (C57BL/6JOlaHsd) were maintained with three different diets: high phytoestrogen (ca. 400 mg/kg genistein), low phytoestrogen (ca. 10 mg/kg genistein) and standard breeding diet (ca. 120 mg/kg genistein). Mice fed a high phytoestrogen diet had a high yield of plugs, embryos, and injectable embryos, as well as producing good quality embryos. Results from donor mice fed a low phytoestrogen diet were consistently but only slightly inferior, whereas mice fed a standard diet performed the poorest. Interestingly, the largest number of born and weaned offspring were observed when recipient females received embryos from the standard diet group. Sperm yield and quality of stud males did not differ between the groups. We surmize that for experimental endpoints requiring fertilized embryos it may be more beneficial to feed mice a diet containing phytoestrogen, but if the goal is to produce transgenic mice, a diet high in phytoestrogen may be inadvisable. In conclusion, care should be taken when selecting a diet for experimental mouse colonies as phytoestrogen could influence the study outcome.

Identification of the Sex of Pre-implantation Mouse Embryos Using a Marked Y Chromosome and CRISPR/Cas9.

Although numerous attempts have been made to alter the sex ratio of the progeny of mammals, the limitations of current technologies have prevented their widespread use in farm animals. The presence or absence of a Y chromosome determines whether a mammalian embryo develops as a male or female, and non-invasive genetic reporters such as fluorescence protein markers have been intensively applied in a variety of fields of research. To develop a non-invasive and instantaneous method for advance determination of the sex of embryos, we developed a Y chromosome-linked eGFP mouse line that stably expresses green fluorescent protein under the control of the CAG promoter. The development of the CRISPR/Cas9 system has made it easy to deliver an exogenous gene to a specific locus of a genome, and linking a tracer to the Y chromosome has simplified the process of predicting the sex of embryos collected by mating a Y-Chr-eGFP transgenic male with a wild-type female. XY embryos appeared green, under a fluorescence microscope, and XX embryos did not. Y chromosome-linked genes were amplified by nested PCR to further confirm the accuracy of this method, and the simultaneous transplantation of green and non-green embryos into foster mothers indicated that 100% accuracy was achieved by this method. Thus, the Y-Chr-eGFP mouse line provides an expeditious and accurate approach for sexing pre-implantation embryos and can be efficiently used for the pre-selection of sex.

Switchable genome editing via genetic code expansion.

Multiple applications of genome editing by CRISPR-Cas9 necessitate stringent regulation and Cas9 variants have accordingly been generated whose activity responds to small ligands, temperature or light. However, these approaches are often impracticable, for example in clinical therapeutic genome editing in situ or gene drives in which environmentally-compatible control is paramount. With this in mind, we have developed heritable Cas9-mediated mammalian genome editing that is acutely controlled by the cheap lysine derivative, Lys(Boc) (BOC). Genetic code expansion permitted non-physiological BOC incorporation such that Cas9 (Cas9BOC) was expressed in a full-length, active form in cultured somatic cells only after BOC exposure. Stringently BOC-dependent, heritable editing of transgenic and native genomic loci occurred when Cas9BOC was expressed at the onset of mouse embryonic development from cRNA or Cas9BOC transgenic females. The tightly controlled Cas9 editing system reported here promises to have broad applications and is a first step towards purposed, spatiotemporal gene drive regulation over large geographical ranges.

Efectos del ejercicio físico y pautas básicas para su prescripción en la enfermedad de Alzheimer / Efeitos do exercício físico e diretrizes básicas para sua prescrição na doença de Alzheimer / Effects of physical exercise and basically orientations for prescription in Alzheimer’s Disease

El presente estudio tiene como objetivo actualizar el estado del arte con respecto a los beneficios potenciales que el ejercicio físico tiene sobre la enfermedad de Alzheimer. En primer lugar, se presentan los motivos por los que el ejercicio podría ser beneficioso, a través de la descripción de los efectos que su práctica tiene sobre aspectos metabólicos y neuropatológicos relacionados con esta enfermedad. En segundo lugar, se analizan las diferentes respuestas orgánicas que podrían ser moduladas a través del ejercicio y los cambios que este provoca en los marcadores biológicos de la enfermedad de Alzheimer. En tercer lugar, se muestran los hallazgos de los principales estudios que han propuesto la realización de programas de ejercicio en personas diagnosticadas de enfermedad de Alzheimer, a través de la descripción de los resultados obtenidos en los mismos. Finalmente, se presentan recomendaciones prácticas y propuestas de actuación para prescribir ejercicio físico en esta población (AU)

O presente estudo tem como objetivo atualizar o estado da arte sobre os potenciais benefícios do exercício físico na doença de Alzheimer. Em primeiro lugar, as razões pelas quais o exercício pode ser benéfico, são apresentadas através da descrição dos efeitos de sua prática nos aspectos metabólicos e neuropatológicos da doença. Em segundo lugar, são analisadas as diferentes respostas orgânicas que podem ser moduladas através dos exercícios e as mudanças provocadas em marcadores biológicos da doença de Alzheimer. Em terceiro lugar, são mostrados os achados dos principais estudos que propuseram a realização de programas de exercício para pessoas diagnosticadas com doença de Alzheimer, por meio da descrição dos resultados obtidos da mesma. Finalmente, são apresentadas recomendações práticas e propostas de ação para prescrever exercício nesta população(AU)

The aim of this study is to update the state of the art regarding the potential benefits of physical exercise on Alzheimer's disease. Firstly, the reasons why physical exercise may be beneficial are discussed through the impact that its performance has on the metabolic and neuropathological aspects related to this disease. Secondly, the different organic adaptations that could be modulated by means of exercising as well as the changes that could be induced through its practice on Alzheimer's disease biomarkers are analyzed. Thirdly, the findings of the main studies that have proposed the performance of exercise programs on people diagnosed with Alzheimer's disease are discussed trough the description of the obtained results. Finally, some practical recommendations and guidelines for prescribing physical exercise on this population are shown (AU)

Mosaic pattern of Cre recombinase expression in cochlear outer hair cells of the Brn3.1 Cre mouse.

The Brn3.1 gene encodes for the protein Brn3.1, which is a member of the POU-IV class of transcription factors. Mutation leads to nonsyndromic human progressive hearing loss (DFNA15). To investigate the suitability of the Brn3.1 promoter for Cre recombinase-induced genetic recombination in cochlear hair cells, we established a transgenic Brn3.1 Cre mouse. This mouse line was crossbred with floxed ROSA26 and ROSA26 reporter mice. The cochleae were histologically analysed in cryosections at E16.5 and whole-mount preparations from P2 until P85. In addition, mice from all used strains and their recombinant offspring were tested electrophysiologically by auditory brainstem responses (ABR) and distorsion product otoacoustic emissions (DPOAE). Cre recombinase activity could be detected in P14 and P21 animals in a mosaic pattern in 26.3 and 9.9% of the outer hair cells, respectively. All investigated mice showed normal ABR and DPOAE values, indicating that neither insertion of the internal ribosome entry site (IRES) Cre cassette into the Brn3.1 gene led to abnormal auditory development nor did the reporter strains show inherited hearing disorders. This study shows that Cre expression under the control of the Brn3.1 promoter is feasible and that the insertion of the internal ribosome entry site Cre cassette into this locus exerted no effects on hearing development. Because of the inconstant pattern and the limited duration of expression, the application of the developed mouse line might be restricted. Also, the unchanged hearing capacity and structural integrity of the organ of Corti in available reporter lines indicate that they may be useful tools for hearing research.

Identification of novel hypomorphic and null mutations in Klf1 derived from a genetic screen for modifiers of α-globin transgene variegation.

Position-effect variegation of transgene expression is sensitive to the chromatin state. We previously reported a forward genetic screen in mice carrying a variegated α-globin GFP transgene to find novel genes encoding epigenetic regulators. We named the phenovariant strains "Mommes" for modifiers of murine metastable epialleles. Here we report positional cloning of mutations in two Momme strains which result in suppression of variegation. Both strains harbour point mutations in the erythroid transcription factor, Klf1. One (D11) generates a stop codon in the zinc finger domain and a homozygous null phenotype. The other (D45) generates an amino acid transversion (H350R) within a conserved linker between zinc fingers two and three. Homozygous MommeD45 mice have chronic microcytic anaemia which models the phenotype in a recently described family. This is the first genetic evidence that the linkers between the zinc fingers of transcription factors have a function beyond that of a simple spacer.

Visualizing spatiotemporal dynamics of multicellular cell-cycle progressions with fucci technology.

The visualization of cell-cycle behavior of individual cells within complex tissues presents an irresistible challenge to biologists studying multicellular structures. However, the transition from G1 to S in the cell cycle is difficult to monitor despite the fact that the process involves the critical decision to initiate a new round of DNA replication. Here, we use ubiquitination oscillators that control cell-cycle transitions to develop genetically encoded fluorescent probes for cell-cycle progression. Fucci (fluorescent ubiquitination-based cell-cycle indicator) probes exploit the regulation of cell-cycle-dependent ubiquitination to effectively label individual nuclei in G1 phase red, and those in S/G2/M phases green. Cultured cells and transgenic mice constitutively expressing the probes have been generated, such that every cell nucleus shows either red or green fluorescence. This protocol details two experiments that use biological samples expressing Fucci probes. One experiment involves time-lapse imaging of cells stably expressing a Fucci derivative (Fucci2), which allows for the exploration of the spatiotemporal patterns of cell-cycle dynamics during structural and behavioral changes of cultured cells. The other experiment involves large-field, high-resolution imaging of fixed sections of Fucci transgenic mouse embryos, which provides maps that illustrate cell proliferation versus differentiation in various developing organs.

Nitric oxide synthase-3 promotes embryonic development of atrioventricular valves.

Nitric oxide synthase-3 (NOS3) has recently been shown to promote endothelial-to-mesenchymal transition (EndMT) in the developing atrioventricular (AV) canal. The present study was aimed to investigate the role of NOS3 in embryonic development of AV valves. We hypothesized that NOS3 promotes embryonic development of AV valves via EndMT. To test this hypothesis, morphological and functional analysis of AV valves were performed in wild-type (WT) and NOS3(-/-) mice at postnatal day 0. Our data show that the overall size and length of mitral and tricuspid valves were decreased in NOS3(-/-) compared with WT mice. Echocardiographic assessment showed significant regurgitation of mitral and tricuspid valves during systole in NOS3(-/-) mice. These phenotypes were all rescued by cardiac specific NOS3 overexpression. To assess EndMT, immunostaining of Snail1 was performed in the embryonic heart. Both total mesenchymal and Snail1(+) cells in the AV cushion were decreased in NOS3(-/-) compared with WT mice at E10.5 and E12.5, which was completely restored by cardiac specific NOS3 overexpression. In cultured embryonic hearts, NOS3 promoted transforming growth factor (TGFß), bone morphogenetic protein (BMP2) and Snail1expression through cGMP. Furthermore, mesenchymal cell formation and migration from cultured AV cushion explants were decreased in the NOS3(-/-) compared with WT mice. We conclude that NOS3 promotes AV valve formation during embryonic heart development and deficiency in NOS3 results in AV valve insufficiency.

Nonsurgical embryo transfer device compared with surgery for embryo transfer in mice.

The use of a murine nonsurgical embryo transfer (NSET) device had been described previously for the transfer of blastocysts, morulae, DNA-microinjected embryos, and embryonic stem cell-containing embryos to create genetically modified mice. However, physiologic effects of the NSET device and traditional surgical methods had not been compared directly. Here we used electrocardiography and fecal corticosterone levels to monitor pseudopregnant mice that underwent anesthesia only, the NSET procedure with or without anesthesia, or surgery. These procedures were performed without the use of actual embryos, to focus on effects of the procedures themselves rather than on any physiologic effects due to the deposition of embryos. As compared with surgery and anesthesia, the NSET procedure was associated with less fluctuation in cardiac rhythm and lower levels of the stress biomarker fecal corticosterone. These results indicate that use of the NSET device avoids these physi- ological perturbations as well as other disadvantages of surgery (for example, postoperative pain and need for postoperative analgesia) and therefore provides a valuable refinement of existing mouse embryo transfer procedures.

Efficient production of transgenic mice by intracytoplasmic injection of streptolysin-O-treated spermatozoa.

Many methods for efficient production of transgenic animals for biomedical research have been developed. Despite great improvements in transgenesis rates resulting from the use of intracytoplasmic sperm injection (ICSI), the ICSI-based sperm-mediated gene-transfer (iSMGT) technique is still not optimal in terms of sperm permeabilization efficiency and subsequent development. Here, we demonstrate that streptolysin-O (SLO) can efficiently permeabilize mouse spermatozoa, leading to improved developmental competence and high transgenesis rates in iSMGT embryos and pups. In particular, the most efficient production of iSMGT-transgenic embryos resulted from pretreatment with 5 U/ml SLO for 30 min and co-incubation with 1.0 ng/µl of an EGFP expression vector. By incubating spermatozoa with Cy-3-labelled DNA, we found that fluorescence intensity was prominently detected in the head region of SLO-treated spermatozoa. In addition, blastocyst development rate and blastomere survival were greatly improved by iSMGT using SLO-treated spermatozoa (iSMGT-SLO) as compared to freeze-thawed spermatozoa. Consistent with this, a high proportion of transgenic offspring was obtained by iSMGT-SLO after transfer into foster mothers, reaching 10.6% of the number of oocytes used (42.3% among pups). Together with successful germline transmission of transgenes in all founders analyzed, our data strongly suggest that SLO makes spermatozoa amenable to exogenous DNA uptake, and that the iSMGT-SLO technique is an efficient method for production of transgenic animals for biomedical research.

Androgenetic haploid embryonic stem cells produce live transgenic mice.

Haploids and double haploids are important resources for studying recessive traits and have large impacts on crop breeding, but natural haploids are rare in animals. Mammalian haploids are restricted to germline cells and are occasionally found in tumours with massive chromosome loss. Recent success in establishing haploid embryonic stem (ES) cells in medaka fish and mice raised the possibility of using engineered mammalian haploid cells in genetic studies. However, the availability and functional characterization of mammalian haploid ES cells are still limited. Here we show that mouse androgenetic haploid ES (ahES) cell lines can be established by transferring sperm into an enucleated oocyte. The ahES cells maintain haploidy and stable growth over 30 passages, express pluripotent markers, possess the ability to differentiate into all three germ layers in vitro and in vivo, and contribute to germlines of chimaeras when injected into blastocysts. Although epigenetically distinct from sperm cells, the ahES cells can produce viable and fertile progenies after intracytoplasmic injection into mature oocytes. The oocyte-injection procedure can also produce viable transgenic mice from genetically engineered ahES cells. Our findings show the developmental pluripotency of androgenentic haploids and provide a new tool to quickly produce genetic models for recessive traits. They may also shed new light on assisted reproduction.

SOX2 redirects the developmental fate of the intestinal epithelium toward a premature gastric phenotype.

Various factors play an essential role in patterning the digestive tract. During development, Sox2 and Cdx2 are exclusively expressed in the anterior and the posterior parts of the primitive gut, respectively. However, it is unclear whether these transcription factors influence each other in determining specification of the naïve gut endoderm. We therefore investigated whether Sox2 redirects the fate of the prospective intestinal part of the primitive gut. Ectopic expression of Sox2 in the posterior region of the primitive gut caused anteriorization of the gut toward a gastric-like phenotype. Sox2 activated the foregut transcriptional program, in spite of sustained co-expression of endogenous Cdx2. However, binding of Cdx2 to its genomic targets and thus its transcriptional activity was strongly reduced. Recent findings indicate that endodermal Cdx2 is required to initiate the intestinal program and to suppress anterior cell fate. Our findings suggest that reduced Cdx2 expression by itself is not sufficient to cause anteriorization, but that Sox2 expression is also required. Moreover, it indicates that the balance between Sox2 and Cdx2 function is essential for proper specification of the primitive gut and that Sox2 may overrule the initial patterning of the primitive gut, emphasizing the plasticity of the primitive gut.

Inducible recombination in the cardiac conduction system of minK: CreERT² BAC transgenic mice.

Inducible Cre recombination is a powerful technology that allows for spatial and temporal modulation of gene expression in vivo. Diseases of the cardiac conduction system (CCS) pose a significant clinical burden but are not currently well understood at the molecular level. To enable inducible recombination in the murine CCS, we created a minK:CreERT(2) bacterial artificial chromosome (BAC) transgenic mouse line. Cre activity is present after tamoxifen administration in the atrioventricular (AV) node, AV bundle, and bundle branches of adult transgenic mice. We anticipate that by enabling inducible recombination specifically in the AV node, bundle, and bundle branches, minK:CreERT(2) BAC transgenic mice will prove useful in advancing our understanding of CCS disease and function.

Dual promoter lentiviral vector generates transgenic mice expressing E2-CSFV glycoprotein in their milk, but impairs early identification of transgenic embryos.

Lentiviral vectors containing the green fluorescent protein gene have been successfully used to select transgenic embryos before transfer to a surrogate mother. However, there are apparently no reports regarding early detection of transgenic embryos using a lentiviral vector carrying an additional transcription unit for tissue-specific expression of a valuable protein. In this study, two HIV-based lentiviral vectors were constructed. The first one contained the green fluorescent protein (GFP) coding sequence driven by the early SV40 promoter (Lv-G), whereas the other contained an additional transcription unit for the expression of E2 glycoprotein from classical swine fever virus, driven by a 1.5 kb αS1casein promoter from water buffalo (Lv-αS1cE2hisG). Microinjection of single-cell mouse embryos with Lv-G lentiviral vector rendered embryos which were GFP-positive, beginning at the four-cell stage. Of 33 mice born, 28 (81%) carried the transgene DNA and 15 (55.5%) were GFP-positive. Microinjection of Lv-αS1cE2hisG lentiviral vector yielded 28 mice born; although 24 (85%) carried the transgene DNA, none were GFP-positive, suggesting that the tissue-specific expression cassette interfered with expression of the ubiquitous trancriptional unit. In Lv-αS1cE2hisG transgenic mice, E2his was expressed in milk as a homodimer (at concentrations ≤ 0.422 mg/mL). This was apparently the first report of expression of a recombinant protein in the milk of transgenic animals generated by lentiviral transgenesis.

Precise pattern of recombination in serotonergic and hypothalamic neurons in a Pdx1-cre transgenic mouse line.

BACKGROUND: Multicellular organisms are characterized by a remarkable diversity of morphologically distinct and functionally specialized cell types. Transgenic techniques for the manipulation of gene expression in specific cellular populations are highly useful for elucidating the development and function of these cellular populations. Given notable similarities in developmental gene expression between pancreatic ß-cells and serotonergic neurons, we examined the pattern of Cre-mediated recombination in the nervous system of a widely used mouse line, Pdx1-cre (formal designation, Tg(Ipf1-cre)89.1Dam), in which the expression of Cre recombinase is driven by regulatory elements upstream of the pdx1 (pancreatic-duodenal homeobox 1) gene. METHODS: Single (hemizygous) transgenic mice of the pdx1-creCre/0 genotype were bred to single (hemizygous) transgenic reporter mice (Z/EG and rosa26R lines). Recombination pattern was examined in offspring using whole-mount and sectioned histological preparations at e9.5, e10.5, e11.5, e16.5 and adult developmental stages. RESULTS: In addition to the previously reported pancreatic recombination, recombination in the developing nervous system and inner ear formation was observed. In the central nervous system, we observed a highly specific pattern of recombination in neuronal progenitors in the ventral brainstem and diencephalon. In the rostral brainstem (r1-r2), recombination occurred in newborn serotonergic neurons. In the caudal brainstem, recombination occurred in non-serotonergic cells. In the adult, this resulted in reporter expression in the vast majority of forebrain-projecting serotonergic neurons (located in the dorsal and median raphe nuclei) but in none of the spinal cord-projecting serotonergic neurons of the caudal raphe nuclei. In the adult caudal brainstem, reporter expression was widespread in the inferior olive nucleus. In the adult hypothalamus, recombination was observed in the arcuate nucleus and dorsomedial hypothalamus. Recombination was not observed in any other region of the central nervous system. Neuronal expression of endogenous pdx1 was not observed. CONCLUSIONS: The Pdx1-cre mouse line, and the regulatory elements contained in the corresponding transgene, could be a valuable tool for targeted genetic manipulation of developing forebrain-projecting serotonergic neurons and several other unique neuronal sub-populations. These results suggest that investigators employing this mouse line for studies of pancreatic function should consider the possible contributions of central nervous system effects towards resulting phenotypes.

Cryopreservation for broader production of transgenic mice by DNA injection into zygotes.

Mutant mice are indispensable to biological and medical research, and transgenic mouse production by DNA injection into zygotes has been an important method for producing these mice which are used to examine the over-expression of genes and to analyze gene transcriptional regulatory sequences. Recently, cryopreservation of zygotes by a simple vitrification method has become popular, saving the labor of isolating zygotes following each injection. However, the DNA injection technique requires training in the use of special equipment, and the injection cannot be accomplished routinely in every laboratory. The exchange of live mice also risks the propagation of common murine pathogens and possible escape of the animals; therefore the transfer of mice in frozen zygotes or embryos is recommended. Here we propose injecting DNA into frozen and thawed zygotes, refreezing them before transportation to any destination, where they can be thawed and developed into pups. The rate of transgenic mouse production using this method does not decrease significantly, even if zygotes are frozen and thawed before and after their DNA injection, and will make transgenic studies more popular on a worldwide scale.

An efficient method for generating transgenic mice using NaOH-treated spermatozoa.

Transgenic (Tg) animals are widely used in researching the characteristics of exogenous genes. Intracytoplasmic sperm injection (ICSI)-mediated transgenesis (ICSI-Tr) has been a useful method for generating Tg animals, especially in the mouse. However, the original methods using freeze-thawed spermatozoa showed severe chromosomal damage and low offspring rates after embryo transfer. Herein, we describe an improved method to generate Tg mice efficiently using a simple pretreatment of spermatozoa with 10 mM NaOH. These spermatozoa lost their plasma membrane and tail, while still maintaining nuclear integrity. Sperm heads were mixed with 0.5-5 ng/microl of the transgene for enhanced green fluorescent protein (EGFP) for 3 min to 1 h at room temperature and were then microinjected into oocytes by ICSI. The best results were obtained when treated spermatozoa were incubated with 2 ng/microl of EGFP for 10 min; 55.6% of injected embryos developed to the blastocyst stage, and more than half (56.9%) of them displayed EGFP fluorescence. Under these conditions, 12 pups of 34 offspring were positive for the transgene after transfer at the 2-cell stage into pseudopregnant recipient mice (a high rate [10.2%] from manipulated embryos). This method was found to be suitable for hybrid and inbred strains of mouse such as C57BL/6 and 129X1/Sv. Thus, a simple sperm pretreatment with NaOH before ICSI-Tr resulted in an efficient insertion of an exogenous gene into the host genome. This method allows for easy production of Tg mice, requiring fewer oocytes for micromanipulation than classical methods.

Generation of mice with a conditional allele for Ift172.

Ift172 encodes a gene product that is part of a complex that mediates intraflagellar transport (IFT), a process necessary for the genesis and maintenance of cilia. Genetic studies in mice have offered evidence that Ift172 also plays a role in hedgehog signaling. Disruption of Ift172 in mice is associated with lethality at about embryonic day 11, limiting studies to understand the role for Ift172 in later development and the adult. To further our understanding of the later roles of Ift172, we have generated mice with a conditional allele for Ift172. We have confirmed the phenotype of the disrupted allele by using CRE expression directed by the prx1 enhancer to disrupt the conditional Ift172 allele in the developing limb.

Studying autoimmunity by in vivo RNA interference.

The occurrence of autoimmunity is strongly associated with multiple gene variants that predispose individuals to disease. The identification of the gene polymorphisms that modulate disease susceptibility is key to our understanding of disease etiology and pathogenesis. While genetic studies in humans have uncovered several associations and have provided possible candidate genes for further study, the use of animal models is indispensable for detailed functional studies. In order to facilitate the genetic manipulation of experimental models of autoimmunity, we employ lentiviral transgenesis in combination with RNA interference (RNAi). This approach bypasses the need for targeted mutagenesis of embryonic stem cells and/or backcrossing of genetically modified animals onto the relevant genetic background. Lentiviral RNAi offers several advantages compared to conventional transgenesis or knockout technology, and these, as well as the technique's weaknesses, are discussed herein.