DNA uptake in swine sperm: Effect of plasmid topology and methyl‐beta‐cyclodextrin‐mediated cholesterol depletion

Sperm‐mediated gene transfer (SMGT), the ability of sperm cells to spontaneously incorporate exogenous DNA and to deliver it to oocytes during fertilization, has been proposed as an easy and efficient method for producing transgenic animals. SMGT is still undergoing development and optimization to improve the uptake efficiency of foreign DNA by sperm cells, which is a preliminary, yet critical, step for successful SMGT. Towards this aim, we developed a quantitative, real‐time PCR‐based assay to assess the absolute number of exogenous plasmids internalized into the spermatozoon. Using this technique, we found that the circular form of the DNA is more efficiently taken up than the linearized form. We also found that DNA internalization into the nucleus of porcine sperm cells is better under specific methyl‐β‐cyclodextrin (MCD)‐treated conditions, where the plasma membrane properties were altered without significantly compromising sperm physiology. These results provide the first evidence that membrane cholesterol depletion by MCD might represent a novel strategy for enhancing the ability of sperm to take up heterologous DNA. Mol. Reprod. Dev. 79: 853–860, 2012. © 2012 Wiley Periodicals, Inc.     

Association of rabbit sperm cells with exogenous DNA

The ability of rabbit spermatozoa to bind exogenous DNA during sperm-mediated gene transfer (SMGT) was tested in our study. Fresh collected semen, or fully capacitated sperm cells, was co-cultured with plasmid DNA labeled with tetramethyrodamine-6-dUTP. Fluorescent spermatozoa were counted before and after DNaseI treatment. Results showed that fluorescent-labeled plasmid DNA could be taken up by capacitated rabbit sperm cells. 66% spermatozoa carried exogenous DNA in the presence of lipofectin. Bovine serum albumin could block this process effectively. Associated DNA was mainly located in the posterior area of the sperm head. In order to verify whether exogenous DNA was carried into the embryo and expressed in the offspring, further SMGT experiments were carried out using the pHM-CR plasmid which contains LacZ and Neomycin genes. beta-galactosidase was expressed in different stages of embryo development and in the tissues of young rabbit as detected by using X-gal staining. Large portion of embryos survived under the selection pressure in G418 containing medium, after SMGT. Transgene integration was further verified by PCR analysis. These results confirmed the ability of rabbit sperm cells to carry transgene into the embryo during in vitro fertilization.     

Sperm mediated gene transfer in pig: Selection of donor boars and optimization of DNA uptake

Transgenic animals are produced primarily by microinjecting exogenous DNA into the male pronuclei of a zygote. Microinjection is successful in mice but not efficient in farm animals, limiting its general utility. We have pursued an alternative technology for producing transgenic animals: Sperm Mediated Gene Transfer (SMGT). Based on our finding that sperm cells bind and internalize exogenous DNA, we used sperm as a vector for transmitting, not only their own DNA, but also, the exogenously-introduced gene of interest to the zygote. SMGT is highly efficient (up to greater than 80%) and relatively inexpensive; it can be used in species refractory to microinjection, whenever reproduction is mediated by gametes. In this report, we describe the procedure for selection of sperm donors and optimization of DNA uptake that are the key steps for the successful outcome of SMGT. We found that the nominal parameters that boar sperm should possess to serve as a good vector for exogenous DNA are the quality of semen based on standard parameters used in conventional animal breeding programs (volume, concentration, presence of abnormal sperm cells, motility at time of collection, and high progressive motility after 2 hr) and the ability of the sperm cells to take up and internalize exogenous DNA. The results described provide significant advances in SMGT technology applied to pigs, so that transgenic pigs can be efficiently obtained. Mol.     

精子因素对精子载体法制备转基因山羊的影响

精子具有主动结合、转运、整合外源DNA的能力,并在受精时导入卵母细胞,获得转基因动物.精子介导基因转移(sperm-mediated gene transfer,SMGT)是目前获得转基因动物简单而高效的方法之一.精子因素是影响SMGT方法生产转基因动物的重要方面.本论文结合我们的研究针对转染用山羊(Capra hircus)精液的来源、精子质膜完整性、精液品质及发育阶段等精子因素影响精子结合外源DNA和SMGT方法生产转基因山羊的效率进行了论述,并从这些影响因素入手,提出了筛选精子供体、保持精液品质、调控质膜等措施,提高精子转染外源DNA能力和生产转基因动物的效率.     

精子结合外源DNA的特征及影响因素

外源DNA与精子相互作用后的定位及内化率是精子载体法制备转基因动物的关键环节。实验以标记的DNA片段为示踪材料,就精子与外源DNA相互作用的基本特征及影响因素进行了研究。结果表明：山羊精子可自发性结合外源DNA,外源DNA最初结合于顶体后区质膜外表面,随后部分内化进入细胞内。精子对外源DNA的结合和内化能力随供体的不同而差异明显,在实验所检查的35只公羊中,结合率（DNaseⅠ消化前）波动于4.6% ~ 62.4%,内化率（DNaseⅠ消化后）波动于2.1% ~ 53.8%,个体间差异显著（P<0.01）。对于同一供体的精子而言,阻止DNA结合的最主要因素是精浆,与射出的原精液相比,洗涤后精子的结合率和内化率分别提高了3倍和5倍;其次精子获能也将导致结合率和内化率降低（P<0.01）。死精子不能完成外源DNA的内化过程,但反复冻融导致质膜破裂的死精子具有更高的结合率,而且阳性率与动物个体无关。上述结果提示,筛选合适的精子供体,采用优化的转染处理方法是提高精子载体方法效率的前提和保证。     

The negative effects of exogenous DNA binding on porcine spermatozoa are caused by removal of seminal fluid

Sperm-mediated gene transfer (SMGT) might become the most efficient and cost effective technique to generate transgenic animals, which will significantly increase their application in biomedical research and in commercial production. Despite some successes, the technique has remained controversial for almost 20 years and despite number of studies the reasons for poor reproducibility of this promising technology has not been understood. We suggest that the reason for poor reproducibility is the presence of natural defences against exogenous DNA invasion acting in spermatozoa or in embryo. Based on previous reports we have investigated the effect of foreign DNA binding on spermatozoa by monitoring motility, viability and genomic DNA damage. Evaluation of DNA binding in sperm collected from 16 boars demonstrated that 28-45% of the added pEGFP plasmid was bound to spermatozoa with 9-32% being internalized in sperm nucleus. In agreement with previous reports, our results demonstrated that the pEGFP-treated sperm show an average a 2-fold decrease in motility (p<0.05), 5-fold decrease in progressive motility (p<0.05), and 1.4-fold increase in number of sperm with highly damaged DNA (p<0.05) as detected by Comet assay. In contrast with previous reports, we demonstrate that all such changes were associated with the removal of seminal plasma during the washing step and not with foreign DNA binding per se. We suggest that poor reproducibility of SMGT most likely result from selection against DNA-loaded sperm at later stages of fertilization.     

Exogenous DNA uptake by South American catfish (Rhamdia quelen) spermatozoa after seminal plasma removal

Sperm from different species shows biological differences, determining the success or failure of the sperm-mediated gene transfer (SMGT) technique. There is evidence that exogenous DNA uptake by the spermatozoa is a species-specific and highly regulated phenomenon. Problems involving SMGT procedures might be related to activation of defenses in spermatozoa and in seminal plasma such as DNase enzymes. The objective in the present study was to transfect South American catfish spermatozoa after seminal plasma removal. Seminal plasma had a strong DNase activity that is reduced after sperm washes in isosmotic solution, in which Western blot analysis demonstrated a reduction in the DNase content after washes and Southern blot evaluations show the presence of plasmid after sperm washes. The seminal plasma DNase digests exogenous DNA in a few minutes and has an optimal activity at 43°C. Also, EDTA at 30 mM concentration inhibits the DNase activity. Using PCR the pEGFP vector was internalized by sperm cells even at lesser concentrations (5-40 ng/10(6) spermatozoa) without motility loss after seminal plasma removal. Conversely, using greater pEGFP concentrations (100 ng/10(6) spermatozoa), there were no motile cells, suggesting toxicity of exogenous DNA for sperm cells. These results are interpreted to provide information that can improve the protocol for generation of transgenic South American catfish.     

Sperm-mediated gene transfer-treated spermatozoa maintain good quality parameters and in vitro fertilization ability in swine

A simple and efficient method for producing multitransgenic animals is required for medical and veterinary applications. Sperm-mediated gene transfer (SMGT) is an effective method for introducing multiple genes into pigs (Sus, Sus scrofa). The major benefits of this technique are the high efficiency, low cost, and ease of use compared with that of other methods: Sperm-mediated gene transfer does not require embryo handling or expensive equipment. The aim of this study was to investigate the influence of SMGT treatment and exogenous DNA uptake on sperm quality. Even after a coincubation with a 20-fold larger amount (100 μg/mL) of DNA than usual (5 μg/mL), sperm quality parameters were not significantly affected, confirming the hypothesis that the SMGT protocol itself or the amount of bound DNA do not compromise the possibility of an extended employment of SMGT. More importantly, we found that semen used for in vitro fertilization 24 h after DNA uptake gave good cleavage (60% vs. 58%, treated vs. control) and developmental rates definitely positive (41% vs. 48%, treated vs. control). These good results are connected to a competitive efficiency of transformation (62%) due to the numerous improvements in SMGT technique. We demonstrate that SMGT-treated spermatozoa retain good quality and fertilization potential for at least 24 h, expanding the possibility to apply transgenesis in field conditions in swine, where the greatest hurdles are fertilization timing and plain procedure.     

Evaluation of DNase activity in seminal plasma and uptake of exogenous DNA by spermatozoa of the Brazilian flounder Paralichthys orbignyanus

Sperm mediated gene transfer (SMGT) has been successfully used in mammals, amphibians, birds, and some invertebrates. In fish, this methodology has failed or had poor efficiency for the production of transgenic specimens, presumably because the processes regulating the interaction between spermatozoa and exogenous DNA are not well understood. Therefore, the objective was to develop a SMGT protocol for the Brazilian flounder Paralichthys orbignyanus, with an emphasis on the role of seminal plasma DNase on exogenous DNA uptake by fish spermatozoa. In this study, there was strong DNase activity in the seminal plasma of P. orbignyanus; however, this DNase activity was decreased or eliminated by washing the spermatozoa with solutions containing EDTA (DNase activity was completely inhibited by 40 mM EDTA). Three washing solutions were tested, all of which maintained sperm quality. Moreover, it was determined that the no more than 50 ng of exogenous DNA/10(6) cells should be used for SMGT in fish. Finally, it was demonstrated that fish spermatozoa were capable of spontaneous uptake of exogenous DNA after elimination of DNase activity; this was confirmed by exogenous DNA amplification (PCR using sperm genomic DNA as a template) after DNase I treatment. We concluded that whereas DNase activity was an important obstacle for exogenous DNA uptake by fish spermatozoa; controlling this activity improved the efficiency of SMGT in fish.     

Sperm-mediated gene transfer–treated spermatozoa maintain good quality parameters and in vitro fertilization ability in swine

A simple and efficient method for producing multitransgenic animals is required for medical and veterinary applications. Sperm-mediated gene transfer (SMGT) is an effective method for introducing multiple genes into pigs (Sus, Sus scrofa). The major benefits of this technique are the high efficiency, low cost, and ease of use compared with that of other methods: Sperm-mediated gene transfer does not require embryo handling or expensive equipment. The aim of this study was to investigate the influence of SMGT treatment and exogenous DNA uptake on sperm quality. Even after a coincubation with a 20-fold larger amount (100 μg/mL) of DNA than usual (5 μg/mL), sperm quality parameters were not significantly affected, confirming the hypothesis that the SMGT protocol itself or the amount of bound DNA do not compromise the possibility of an extended employment of SMGT. More importantly, we found that semen used for in vitro fertilization 24 h after DNA uptake gave good cleavage (60% vs. 58%, treated vs. control) and developmental rates definitely positive (41% vs. 48%, treated vs. control). These good results are connected to a competitive efficiency of transformation (62%) due to the numerous improvements in SMGT technique. We demonstrate that SMGT-treated spermatozoa retain good quality and fertilization potential for at least 24 h, expanding the possibility to apply transgenesis in field conditions in swine, where the greatest hurdles are fertilization timing and plain procedure.     

Transient transgene transmission to piglets by intrauterine insemination of spermatozoa incubated with DNA fragments

An efficient and low-cost production of transgenic pigs has significant applications to the pig industry and biomedical science. Generation of transgenic pig by sperm-mediated gene transfer (SMGT) was inexpensive and convenient, and reported with high efficiency. To test the method of SMGT in pigs, we employed deep post-cervical intrauterine insemination of incubated spermatozoa in this study. A test of sperm motility of semen from nine Landrace boars after incubation with radioactively labeled DNA construct indicated that DNA uptake of the sperm was highly correlated with sperm motility at the time of collection. DNA concentration of 50 and 300 microg per one billion sperm was incubated with washed high-motility sperm at 17 degrees C for 2 hr. Twenty one hybrid gilts and sows of Meishan crossed with Large White were inseminated with transgene-incubated sperm and produced 156 piglets. Transgene DNA sequences were identified in 31 piglets by PCR amplification of genomic DNA isolated from piglet ears at the age of 3 days. The deep intrauterine insemination had a higher rate of positive transgenic piglets than regular insemination (29.6% of 98 piglets vs. 3.4% of 58 piglets). However, the exogenous transgene DNA was not detected in any piglets at the age of 70-100 days. Therefore, the results further demonstrated that transgene through incubation with spermatozoa was mostly transiently transmitted to the offspring at early growing stage and lost in adulthood, which may result from episomal DNA replications during cell divisions only at the early stage of development.     

Why do females mate multiply? A review of the genetic benefits

The aim of this review is to consider the potential benefits that females may gain from mating more than once in a single reproductive cycle. The relationship between non-genetic and genetic benefits is briefly explored. We suggest that multiple mating for purely non-genetic benefits is unlikely as it invariably leads to the possibility of genetic benefits as well. We begin by briefly reviewing the main models for genetic benefits to mate choice, and the supporting evidence that choice can increase offspring performance and the sexual attractiveness of sons. We then explain how multiple mating can elevate offspring fitness by increasing the number of potential sires that compete, when this occurs in conjunction with mechanisms of paternity biasing that function in copula or post-copulation. We begin by identifying cases where females use pre-copulatory cues to identify mates prior to remating. In the simplest case, females remate because they identify a superior mate and 'trade up' genetically. The main evidence for this process comes from extra-pair copulation in birds. Second, we note other cases where pre-copulatory cues may be less reliable and females mate with several males to promote post-copulatory mechanisms that bias paternity. Although a distinction is drawn between sperm competition and cryptic female choice, we point out that the genetic benefits to polyandry in terms of producing more viable or sexually attractive offspring do not depend on the exact mechanism that leads to biased paternity. Post-copulatory mechanisms of paternity biasing may: (1) reduce genetic incompatibility between male and female genetic contributions to offspring; (2) increase offspring viability if there is a positive correlation between traits favoured post-copulation and those that improve performance under natural selection; (3) increase the ability of sons to gain paternity when they mate with polyandrous females. A third possibility is that genetic diversity among offspring is directly favoured. This can be due to bet-hedging (due to mate assessment errors or temporal fluctuations in the environment), beneficial interactions between less related siblings or the opportunity to preferentially fertilise eggs with sperm of a specific genotype drawn from a range of stored sperm depending on prevailing environmental conditions. We use case studies from the social insects to provide some concrete examples of the role of genetic diversity among progeny in elevating fitness. We conclude that post-copulatory mechanisms provide a more reliable way of selecting a genetically compatible mate than pre-copulatory mate choice. Some of the best evidence for cryptic female choice by sperm selection is due to selection of more compatible sperm. Two future areas of research seem likely to be profitable. First, more experimental evidence is needed demonstrating that multiple mating increases offspring fitness via genetic gains. Second, the role of multiple mating in promoting assortative fertilization and increasing reproductive isolation between populations may help us to understand sympatric speciation.     

Detection of transgene in progeny at different developmental stages following testis-mediated gene transfer

We recently reported that exogenous DNA injected into testis as a liposome complex can be transferred into the egg via sperm by natural mating and integrated in the genome (testis-mediated gene transfer: TMGT). Here, we studied the efficiency of each of the several liposomes in associating foreign DNA with sperm, the expression of an introduced gene in early embryos, and the presence of the DNA in fetuses and pups at different ages. The CMV/beta-actin/EGFP fusion gene, encapsulated with different liposomes, was injected into rat testis, and spermatozoa in the cauda epididymis were obtained 1, 4, and 14 days after injection. We tested each of the 8 liposomes, and found that only 2, DMRIE-C and SuperFect, led to the detection of foreign DNA on all of the days examined, with relatively higher ratios of rats having positive sperm. By means of TMGT using either of those two liposomes, more than 80% of morula-stage embryos expressed EGFP, as observed by fluorescence microscopy. Then we detected introduced DNA in the progeny by PCR and Southern dot blot, and found that the ratio of animals carrying the foreign DNA decreased as they developed, and that only a part of postpartum progeny were foreign-DNA-positive with high incidence of mosaicism. These results suggest that, although, the success rate is still limited, foreign DNA could be integrated into the genome of the progeny by TMGT at least under specific experimental conditions, the efficiency of which depends largely on the characteristics of the liposome. The results also suggest that TMGT could be applicable to fetal gene therapy as well as to the generation of transgenic animals.     

Efficient and simple production of transgenic mice and rabbits using the new DMSO-sperm mediated exogenous DNA transfer method

A high efficient and simple transgenic technology on mice and rabbits to transfect spermatozoa with exogenous DNA/DMSO complex to obtain transgenic offspring, which is namely called DMSO-sperm mediated gene transfer (SMGT). Mouse sperm could be either directly transfected via injection into testis or cultured in vitro with the plasmed DNA containing the enhanced green fluorescent protein (EGFP) that could be expressed in the embryos and offspring. Then, 36 living transgenic rabbits were produced using the same technology, and the transgenic ratio of 56.3% was detected using PCR and Southern blot. As the controls, the transgenic ratios of 39.6% and 47.8% have also been tested using the liposomes mediated technology of Tfx-50 Reagent or Lipefectamin-2000, respectively. The results show that the female transgenic rabbits, as the mammary gland bioreactor models, could express the human tissue plasminogen activator mutant (htPAm) in their mammary cells when they are adult.     

外源精子基因组整入雌核生殖银鲫卵子创制异源八倍体的有效方法

银鲫(Carassius auratus gibelio Bloth)具有将其他鱼类精子的染色体组、染色体片段并入到卵核中协同发育的能力, 但通过异精雌核生殖自发形成异源八倍体子代的概率极低。研究采用0.25%、0.5%、1%、2%和4%胰蛋白酶溶液处理白鲫精子10min后以及1%胰蛋白溶液处理白鲫精子5min、10min、15min、20min和25min后, 分别与异育银鲫A+系成熟卵子受精; 接着通过比较对照组和不同处理组合中精子结构和活力的变化, 兼顾受精率、孵化率、成活率等繁育指标与较高的子代八倍体率, 建立了一种将外源精子基因组整入雌核生殖银鲫卵子创制异源八倍体的有效方法。即采用1%胰蛋白溶液处理白鲫精子15min后与异育银鲫A+系成熟卵子受精, 子代的平均存活率为(2.4±0.7)%, 平均八倍体率可达(16.3±0.5)%。批量处理并结合流式细胞术筛选6月龄子代, 获得57尾融入有白鲫精子染色体组的异源八倍体成鱼。研究为创制异育银鲫优异异源八倍体种质提供了一个简单易行的方法, 创制的异源八倍体可作为后续培育生长快、抗病能力强的银鲫新品种的核心育种材料。     

Study of genome instability using DNA fingerprinting of the offspring of male mice subjected to chronic low dose gamma irradiation

By a polymerase chain reaction with an arbitrary primer (AP-PCR), the possibility of transmission of genome instability to somatic cells of the offspring (F1 generation) from male parents of mice exposed to chronic low-level gamma-radiation was studied. Male BALB/c mice 15 days after exposure to 10-50 cGy were mated with unirradiated females. Biopsies were taken from tale tips of two month-old offspring mice and DNA was isolated. The primer in the AP-PCR was a 20-mer oligonucleotide flanking the microsatellite locus Atp1b2 on chromosome 11 of the mouse. A comparative analysis of individual fingerprints of AP-PCR products on DNA-templates from the offspring of irradiated and unirradiated male mice revealed an increased variability of microsatellite-associated sequences in the genome of the offspring of the males exposed to 25 and 50 cGy. The DNA-fingerprints of the offspring of male mice exposed to chronic irradiation with the doses 10 and 25 cGy 15 days before fertilization (at the post-meiotic stage of spermatogenesis) showed an increased frequency of "non-parent bands". The results of the study point to the possibility of transmission to the offspring somatic cells of changes increasing genome instability from male parents exposed to chronic low-level radiation prior to fertilization.     

Genome and stresses: Reactions against aggressions,behavior of transposable elements

The action of stresses on the genome can be considered as responses of cells or organisms to external aggressions. Stress factors are of environmental origin (climatic or trophic) or of genomic nature (introduction of foreign genetic material, for example). In both cases, important perturbations can occur and modify hereditary potentialities, creating new combinations compatible with survival; such a situation may increase the variability of the genome, and allow evolutive processes to take place. The behavior of transposable elements under stress conditions is thus of particular interest, since these sequences are sources of mutations and therefore of genetic variability; they may play an important role in population adaptation. The survey of the available experimental results suggests that, although some examples of mutations and transposable elements movements induced by external factors are clearly described, environmental injuries or introduction of foreign material into a genome are not systematically followed by drastic genomic changes.