A new oocyte-holding pipette for intracytoplasmic sperm injection without cytoplasmic aspiration: An experimental study in mouse oocytes

We assessed the feasibility of using a new oocyte-holding pipette (pipette without aspiration, PiWA) for intracytoplasmic sperm injection (ICSI), which prevents cytoplasmic aspiration during microinjection. A pilot experimental study in eight mature mouse oocytes to assess the feasibility of the oocyte-holding PiWA for ICSI procedure. The absence of oocyte degeneration after microinjection and the viability of correct embryo development were also evaluated. The pipette comprises a suction conduit inside an elongated cylindrical body and a funnel-shaped working end, which is dimensioned to hold the oocyte in a tight-fitting manner. Upon aspirating via the suction conduit, the oocyte remains partially trapped inside the funnel and becomes deformed changing the spherical shape of its resting state to an oval shape that tensions the surface and increases the turgor. In all ICSI procedures using the new PiWA, the oocyte membrane presented some resistance but was easily broken when exerting some pressure or small aspiration. The eight oocytes developed, six of which reached the blastocyte stage. The results obtained in this study indicate that the increase in oocyte membrane turgidity caused by PiWA prevents vigorous aspiration of the cytoplasm during spermatozoa microinjection.     

Capillary Microinjection into Protoplasts and Intranuclear Localization of Injected Materials

By a direct microinjection through pressurized glass micropipettes,we injected fluorescent Lucifer Yellow, berberine and berberine-boundDNA into protoplasts isolated from cultured Euphorbia milliicells and from tobacco mesophyll cells. The protoplasts to beinjected were held by a holding pipette with which the cytoplasmor nucleus of the protoplasts could be oriented with referenceto the tip of the injection pipette. Upon microinjection ofa berberine-bound DNA, the nucleus and intranuclear organelles,possibly including nucleolus, specifically exhibited yellowfluorescence due to berberine. This provides a direct evidencethat DNA molecules can be microinjected into the intranuclearcompartment of the protoplasts. The injected protoplasts survivedthe capillary microinjection. (Received August 6, 1984; Accepted November 12, 1984)     

Zygote viability in gene transfer experiments

To learn why some zygotes remain viable after gene transfer while others lyse, we injected DNA into fertilized eggs and compared those that lysed within 1 h of injection with others that retained a normal appearance. Using scanning electron microscopy, we found open holes on the surface of lysed eggs, indicating failure of the plasma membrane to reseal after microinjection. No holes were seen in unlysed eggs, but many of them had membrane alterations suggestive of healed punctures. We also examined aspects of the gene transfer procedure that might influence survival such as the size of injection pipettes and their taper relative to zygote diameter, possible toxicity of the injection medium, the timing of injection, and immediate vs. delayed pipette withdrawal. The only factors that significantly affected cell viability were pipette size and taper, and timing of injection in relation to first cleavage. This suggests that zygote viability correlates inversely with the size of the hole produced by the injection pipette and that damage to the membrane is less successfully repaired as the fertilized egg readies itself for division.     

Cloned mice derived from somatic cell nuclei

In 1997, a cloned sheep "Dolly" was produced by nuclear transfer of somatic cell. The first birth of cloned mice derived from some somatic cells were succeeded in 1998. At present, it is shown that somatic cells, cumulus cells, fibroblasts and Sertoli cells can be used to the study of cloned animal as nuclear donor. In this study investigation was designed to compare with efficiency on the production of cloned embryos by using the microinjection and the electrofusion methods for nuclear transfer. Oocyte enucleation was performed with a micromanipulator. The oocyte was held by holding pipette, and was enucleated using a beveled pipette. Microinjection method: Cell's nucleus injection was carried out by piezo-micromanipulator. Cytochalasin B treated cumulus cell was aspirated into a injection pipette, and was broken its plasma membrane using the injection pipette. Then, the cumulus cell was injected into the enucleated ooplasm directly. Electrofusion method: The cell was aspirated into a beveled pipette, and then an aspirated cell was inserted into perivitelline space. Then, the pair of enucleated oocyte and cell was fused using electrical cell fusion apparatus. The reconstituted embryos were activated after nuclear transfer using St2+. Reconstituted embryos had been produced by the microinjection showed the embryonic development to over 8-cell stages. But, the rate of fragmentation of reconstituted embryos by the microinjection showed a little high rate in comparison with the electrofusion. When some reconstituted embryos by the microinjection were transplanted to pseudopregnant females' oviduct, 9 fetuses were observed at 14 days post coitum.     

Rotationally oscillating drill (Ros-Drill) for mouse ICSI without using mercury

Intracytoplasmic sperm injection (ICSI) is an important assisted reproductive technology (ART). Due to deployment difficulties and low efficiency of the earlier (conventional) version of ICSI, especially in the mouse, a piezo-assisted ICSI technique had evolved as a popular ART methodology in recent years. An important and remaining problem with this technique, however, is that it requires small amounts of mercury to stabilize the pipette tip when piezoelectric force pulses are applied. To eliminate this problem we developed and tested a completely different and mercury-free technology, called the "Ros-Drill" (rotationally oscillating drill). The technique uses microprocessor-controlled rotational oscillations on a spiked micropipette without mercury or piezo. Preliminary experimental results show that this new microinjection technology gives high survival rate (>70% of the injected oocytes) and fertilization rate (>80% of the survived oocytes), and blastocyst formation rates in early trials (approximately 50% of the survived oocytes). Blastocysts created by Ros-Drill ICSI were transferred into the uteruses of pseudopregnant surrogate mothers and healthy pups were born and weaned. The Ros-Drill ICSI technique is automated and therefore; it requires a very short preliminary training for the specialists, as evidenced in many successful biological trials. These advantages of Ros-Drill ICSI over conventional and piezo-assisted ICSI are clearly demonstrated and it appears to have resolved an important problem in reproductive biology.     

哺乳动物显微注精的研究

显微注精过程主要包括固定针和注射针的制备,精子的分离,卵母细胞的采集,卵母细胞的激活和培养,胚胎移植,显微注精不需要精子结构上的完整性,精子核的去凝聚与二硫键有关,卵母细胞的激活对受精成功是必须的。     

Improved developmental potential of rabbit oocytes fertilized by sperm microinjection into the perivitelline space enlarged by hypertonic media

The objectives of the present study were: 1) to develop a simple and more efficient technique for sperm microinjection than is currently available, using the rabbit as a model, and 2) to evaluate the development of rabbit oocytes fertilized by single or multiple sperm microinjection. Hyperosmotic sucrose in phosphate-buffered saline (SPBS) was employed to dehydrate oocytes to increase the perivitelline space for sperm microinjection and prevent possible injury to the vitellus. In the first experiment, 58% (n = 29) oocytes treated with 0.5 M SPBS developed to morulae following multiple sperm microinjection compared, respectively, to 47% (n = 34) and 60% (n = 15) for control IVF with or without sucrose exposure (P greater than 0.05). Blastocyst development from microinjected oocytes, however, was much lower (P less than 0.05) than that of controls (14% vs. 42% and 40%, respectively). Sham operation by puncturing the zona pellucida of the sucrose-treated oocytes with the microinjection pipette did not increase parthenogenesis (P greater than 0.05). In Experiment 2 a smaller-size injection pipette and shorter sucrose exposure time after sperm microinjection resulted in 41% (n = 42) of the oocytes developing into blastocysts for the microinjection group, whereas only 21% (n = 24) developed to blastocysts in the control IVF group (P less than 0.05). When relatively older oocytes (17 hr post ovulation injection) were used to test if microinjection could reduce the time to fertilization and cleavage (Expt. 3), an average of 27% (n = 63) blastocysts resulted from microinjection vs. 0% (n = 28) for the control IVF group.     

Gene transfer into zebrafish by sperm nuclear transplantation

A technique for fertilizing zebrafish eggs by injection of sperm nuclei is described. Eggs that cleave normally can develop into swimming larvae and give rise to fertile adults. If sperm nuclei are preincubated for 20 min with DNA encoding the green fluorescent protein, transgene expression can be detected in all cells of the embryo. The use of condensed sperm nuclei allows injection with a small bore pipette, which is critical for successful injection of the relatively small zebrafish egg. This technique enables the generation of ubiquitously expressing transgenic zebrafish directly by microinjection. Hence, experiments involving transgenic fish can be completed in days, without the need for growing and breeding founders. This technique may also be used to generate transgenic lines, as transgene expression was visible in the offspring of transgenic founders. The method described here is likely to be applicable to other teleosts, such as medaka and salmon.     

Nanoinjection: pronuclear DNA delivery using a charged lance

We present a non-fluidic pronuclear injection method using a silicon microchip ??nanoinjector?? composed of a microelectromechanical system with a solid, electrically conductive lance. Unlike microinjection which uses fluid delivery of DNA, nanoinjection electrically accumulates DNA on the lance, the DNA-coated lance is inserted into the pronucleus, and DNA is electrically released. We compared nanoinjection and microinjection side-by-side over the course of 4?days, injecting 1,013 eggs between the two groups. Nanoinjected zygotes had significantly higher rates of integration per injected embryo, with 6.2?% integration for nanoinjected embryos compared to 1.6?% integration for microinjected embryos. This advantage is explained by nanoinjected zygotes?? significantly higher viability in two stages of development: zygote progress to two-cell stage, and progress from two-cell stage embryos to birth. We observed that 77.6?% of nanoinjected zygotes proceeded to two-cell stage compared to 54.7?% of microinjected zygotes. Of the healthy two-cell stage embryos, 52.4?% from the nanoinjection group and 23.9?% from the microinjected group developed into pups. Structural advantages of the nanoinjector are likely to contribute to the high viability observed. For instance, because charge is used to retain and release DNA, extracellular fluid is not injected into the pronucleus and the cross-sectional area of the nanoinjection lance (0.06???m²) is smaller than that of a microinjection pipette tip (0.78???m²). According to results from the comparative nanoinjection versus microinjection study, we conclude that nanoinjection is a viable method of pronuclear DNA transfer which presents viability advantages over microinjection.     

Microinjection in the chick blastoderm. An improved method to study the extracellular matrix in the living organism

A microinjection technique for the chick blastoderm is described. With a micropipette attached to a de Fonbrune micromanipulator, 25-45 nl of a reagent was injected into the entophyllic crescent of a chick blastoderm explanted in vitro according to New [7]. This procedure offers the advantage of eliminating the concentration variability which was observed after subblastodisc injection, and in contrast to the in ovo techniques, it allows one to stage the blastoderms properly. To check its applicability, testicular hyaluronidase was injected. On the basis of morphological and histochemical observations we ascertained that the experimental procedure itself did not interfere with the results. This method may provide a reliable experimental procedure with which to study the interactions between several macromolecules and the tissues during morphogenesis.     

A highly efficient and automated method of purifying and desalting PCR products for analysis by electrospray ionization mass spectrometry

In this work we present a rapid and fully automated method to purify and desalt PCR products prior to analysis by electrospray ionization mass spectrometry. The protocol employs a commercial pipette tip packed with an anion-exchange resin and comprises four primary steps: tip pretreatment, sample loading, rinsing, and sample elution. This tip-based purification/desalting protocol has two distinct advantages over previously published methods. First, the protocol can be performed either manually (1-12 samples at a time), using a standard p10 manual pipette, or in a fully automated microtiter plate format (96 samples at a time) employing standard laboratory robotics. Additionally, the entire protocol from crude PCR product to an "electrosprayable" analyte solution requires only 10 microl of crude product and takes less than 20 min. Using capillary gel electrophoresis, we demonstrate an overall recovery efficiency of approximately 80% and demonstrate the exquisite desalting efficiency with high-performance electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry. Using an internal mass standard we demonstrate sub-ppm mass measurement error which provides an unambiguous base composition for a 120-mer PCR product.     

Selective Injection System into Hippocampus CA1 via Monitored Theta Oscillation

Methods of cell biology and electrophysiology using dissociated primary cultured neurons allow in vitro study of molecular functions; however, analysis of intact neuronal circuitry is often preferable. To investigate exogenous genes, viral vectors are most commonly injected using a pipette that is inserted from the top of the cortex. Although there are few reports that describe the success rate of injection in detail, it is sometimes difficult to locate the pipette tip accurately within the CA1 pyramidal cell layer because the pyramidal layer is only 0.1 mm thick. In the present study, we have developed a system to inject viral vectors accurately into the mouse hippocampal CA1 pyramidal cell layer using a stereotaxic injection system with simultaneous electrophysiological monitoring of theta oscillation. The pipette tip was positioned reliably based on integrated values of the theta oscillation in the hippocampal CA1 pyramidal cell layer. This approach allows accurate injection of solutions and provides an efficient method of gene transfer using viral vectors into the hippocampus, which can be a useful tool for studies involving the molecular mechanisms of neuronal functions.     

Retrograde Loading of Nerves,Tracts, and Spinal Roots with Fluorescent Dyes

Retrograde labeling of neurons is a standard anatomical method^1,2 that has also been used to load calcium and voltage-sensitive dyes into neurons^3-6. Generally, the dyes are applied as solid crystals or by local pressure injection using glass pipettes. However, this can result in dilution of the dye and reduced labeling intensity, particularly when several hours are required for dye diffusion. Here we demonstrate a simple and low-cost technique for introducing fluorescent and ion-sensitive dyes into neurons using a polyethylene suction pipette filled with the dye solution. This method offers a reliable way for maintaining a high concentration of the dye in contact with axons throughout the loading procedure.     

Characterizing Cell Adhesion by Using Micropipette Aspiration

We have developed a technique to directly quantify cell-substrate adhesion force using micropipette aspiration. The micropipette is positioned perpendicular to the surface of an adherent cell and a constant-rate aspiration pressure is applied. Since the micropipette diameter and the aspiration pressure are our control parameters, we have direct knowledge of the aspiration force, whereas the cell behavior is monitored either in brightfield or interference reflection microscopy. This setup thus allows us to explore a range of geometric parameters, such as projected cell area, adhesion area, or pipette size, as well as dynamical parameters such as the loading rate. We find that cell detachment is a well-defined event occurring at a critical aspiration pressure, and that the detachment force scales with the cell adhesion area (for a given micropipette diameter and loading rate), which defines a critical stress. Taking into account the cell adhesion area, intrinsic parameters of the adhesion bonds, and the loading rate, a minimal model provides an expression for the critical stress that helps rationalize our experimental results.     

Effects of tissue-preparation-induced callose synthesis on est plasmodesma size exclusion limits

Plasmodesmata are often characterised by their size exclusion limit (SEL), which is the molecular weight of the largest dye, introduced by microinjection, that will move from cell to cell. In this study, we investigated whether commonly used techniques for isolation and manipulation of tissues, and microinjection of fluorescent dyes, affected the SEL, and whether any such effects could be ameliorated by inhibiting callose deposition. We examined young root epidermal cells of Arabidopsis thaliana and staminal hair cells of Tradescantia virginiana, two tissues often used in experiments on symplastic transport. Transport in root tips dissected from the main plant body and in stamen hairs removed from the base of the stamen filament was compared with transport in undissected roots and stamen hairs attached to the base of the filament, respectively. Tissues were microinjected with fluorescent dyes (457 Da to > 3 kDa) with or without prior incubation in the callose deposition inhibitors 2-deoxy-D-glucose or aniline blue fluorochrome. In both tissues, dissection reduced the SEL, which was largely prevented by prior incubation in 2-deoxy-D-glucose but not by incubation in aniline blue fluorochrome. Thus, standard methods for tissue preparation can cause sufficient callose deposition to reduce cell-to-cell transport, and this needs to be considered in studies employing microinjection. Introduction of the dyes by pressure injection rather than iontophoresis decreased the SEL in A. thaliana but increased it in T. virginiana, showing that these two injection techniques do not necessarily give identical results and that plasmodesmata in different tissues may respond differently to similar experimental procedures.     

Comparison of analytical and inverse finite element approaches to estimate cell viscoelastic properties by micropipette aspiration

The viscoelastic properties of cells are important in predicting cell deformation under mechanical loading and may reflect cell phenotype or pathological transition. Previous studies have demonstrated that viscoelastic parameters estimated by finite element (FE) analyses of micropipette aspiration (MA) data differ from those estimated by the analytical half-space model. However, it is unclear whether these differences are statistically significant, as previous studies have been based on average cell properties or parametric analyses that do not reflect the inherent experimental and biological variability of real experimental data. To determine whether cell material parameters estimated by the half-space model are significantly different from those predicted by the FE method, we implemented an inverse FE method to estimate the viscoelastic parameters of a population of primary porcine aortic valve interstitial cells tested by MA. We found that inherent differences between the analytical and inverse FE estimation methods resulted in statistically significant differences in individual cell properties. However, in cases with small pipette to cell radius ratios and short loading periods, model-dependent differences were masked by experimental and cell-to-cell variability. Analytical models that account for finite cell-size and loading rate further relaxed the experimental conditions for which accurate cell material parameter estimates could be obtained. These data provide practical guidelines for analysis of MA data that account for the wide range of conditions encountered in typical experiments.     

Geometric characterization of cell membrane of mouse oocytes for ICSI

Intracytoplasmic sperm injection (ICSI) is a broadly utilized assisted reproductive technology. A number of technologies for this procedure have evolved lately, such as the most commonly utilized piezo-assisted ICSI technique (P-ICSI). An important problem with this technique, however, is that it requires a small amount of mercury to stabilize the tip of the penetration micropipette. A completely different and mercury-free injection technology, called the rotationally oscillating drill (Ros-Drill) (RD-ICSI), was recently developed. It uses microprocessor-controlled rotational oscillations of a spiked micropipette after the pipette deforms the membrane to a certain tension level. Inappropriate selection of this initiation instant typically results in cell damage, which ultimately leads to unsuccessful ICSI. During earlier manual clinical tests of Ros-Drill, the technicians' expertise determined this instant in an ad hoc fashion. In this paper, we introduce a computer-vision-based tool to mechanize this process with the objective of maintaining the repeatability and introducing potential automation. Computer images are used for monitoring the membrane deformations and curvature variations as the basis for decision making. The main contribution of this paper is in the specifics of the computer logic to perform the monitoring. These new tools are expected to provide a practicable means for automating the Ros-Drill-assisted ICSI operation.     

完整的供体细胞膜及供体胞质对小鼠体细胞克隆胚发育的影响

利用显微注射和电融合的方法都可以成功地获得体细胞克隆小鼠, 由于电融合法操作耗时, 融合率低, 因而大多数克隆小鼠是采用注射方法。而注射法需要将供体细胞核从细胞中分离出来, 此分离操作有可能导致对DNA的损伤, 曾有人使用直径较粗的注射管进行完整的供体细胞注射, 这种方法操作相对简单而且对供体核没有损伤。为了研究这种方法在小鼠核移植中是否适用, 本实验使用完整的小鼠卵丘细胞作供体, 进行显微注射, 结果显示, 完整的卵丘细胞注入卵母细胞后, 无论在1小时或者6小时激活, 大部分的重构胚在2细胞期碎裂, 而去掉细胞膜的供体体细胞核注入卵母细胞后, 重构胚可以卵裂并进一步发育。卵母细胞去核后不注射供体也发生碎裂, 大部分的孤雌胚(不去核)在完整的卵丘细胞被注入后同样发生碎裂。在供体卵丘细胞刚破膜后即被注入卵胞质和供核被充分剥离后注入两种情况下获得的重构胚的体外发育中, 前者发育各期的比率显著低于后者。这些结果说明完整的卵丘细胞膜阻碍了卵胞质对体细胞核的重编程作用, 造成碎裂; 注入卵胞质的供体质膜和胞质成分影响了克隆胚的体外发育。     

Trans-Uterine Tracer Injections in Mammalian Foetuses

Intra-uterine manipulation of mammalian foetuses for experimental purposes was first described at the beginning of this century (Wolff, 1919). Though numerous publications have appeared since which bear witness to the feasibility of intra-uterine manipulation, its application has remained rather restricted. In this paper we describe a technique for the trans-uterine injection of neuronal tracers into rat foetuses. Uterine wall and foetal membranes are pierced only with a micro pipette, and are thus left virtually intact, preventing loss of amniotic fluid. Surgical mortality is 24% overall, but the experimental success rate is much lower (23%). Even so these results are comparable to more complicated procedures, because the technique is simple (i.e. requires no micro surgical skill), and because up to 6 foetuses can be injected per dam. Technical problems, such as foetal anaesthesia and the detection of false-negative results due to imponderable factors are discussed.     

Trans-Uterine Tracer Injections in Mammalian Foetuses

Intra-uterine manipulation of mammalian foetuses for experimental purposes was first described at the beginning of this century (Wolff, 1919). Though numerous publications have appeared since which bear witness to the feasibility of intra-uterine manipulation, its application has remained rather restricted. In this paper we describe a technique for the trans-uterine injection of neuronal tracers into rat foetuses. Uterine wall and foetal membranes are pierced only with a micro pipette, and are thus left virtually intact, preventing loss of amniotic fluid. Surgical mortality is 24% overall, but the experimental success rate is much lower (23%). Even so these results are comparable to more complicated procedures, because the technique is simple (i.e. requires no micro surgical skill), and because up to 6 foetuses can be injected per dam. Technical problems, such as foetal anaesthesia and the detection of false-negative results due to imponderable factors are discussed.