Effects of acetyl-L-carnitine on lamb oocyte blastocyst rate,ultrastructure, and mitochondrial DNA copy number

Viable lambs can be produced after transfer of in vitro–derived embryos from oocytes harvested from prepubertal lambs. However, this occurs at a much lower efficiency than from adult ewe oocyte donors. The reduced competence of prepubertal oocytes is believed to be due, at least in part, to deficiencies in cytoplasmic maturation. Differences in the cytoplasmic ultrastructure between prepubertal and adult oocytes have been described in the sheep, pig, and cow. Prepubertal lamb oocytes have been shown to have a different distribution of mitochondria and lipid droplets, and less mitochondria and storage vesicles than their adult counterparts. L-carnitine plays a role in supplying energy to the cell by transporting long-chain fatty acids into mitochondria for β-oxidation to produce ATP. Both L-carnitine and its derivative acetyl-L-carnitine have been reported to increase the blastocyst rate of oocytes from mice, cows, and pigs, treated during IVM. L-carnitine has also been shown to increase mitochondrial biogenesis in adipose cells. Therefore, the aims of this study were to determine if treatment of oocytes from prepubertal lambs with acetyl-L-carnitine during IVM could increase the blastocyst rate and alter mitochondria, vesicle, or lipid droplet number, volume, or distribution. The blastocyst rate was doubled in prepubertal lamb oocytes treated with acetyl-L-carnitine when compared to untreated oocytes (10.0% and 4.6%, respectively; P = 0.028). Light microscopy, scanning electron microscopy, and stereology techniques were used to quantify organelles in untreated and acetyl-L-carnitine–treated lamb oocytes, and quantitative polymerase chain reaction methods were used to measure the mitochondrial DNA copy number. There were no differences in mitochondrial volume, number, or mitochondrial DNA copy number. Acetyl-L-carnitine treatment increased the cytoplasmic volume (P = 0.015) of the oocytes, and there were trends toward an increase in the vesicle volume (P = 0.089) and an altered distribution of lipid droplets (P = 0.076). In conclusion, acetyl-L-carnitine can be used to increase the in vitro blastocyst rate of juvenile oocytes and therefore to improve juvenile in vitro embryo transfer methods. These methods can be used for livestock improvement by increasing the rate of genetic gain. Further work is required to identify the contents of the vesicles and confirm the mode of action of acetyl-L-carnitine in improving oocyte competence.     

Advancing maternal age predisposes to mitochondrial damage and loss during maturation of equine oocytes in vitro

In many mammalian species, reproductive success decreases with maternal age. One proposed contributor to this age-related decrease in fertility is a reduction in the quantity or functionality of mitochondria in oocytes. This study examined whether maternal age or (in vitro maturation). IVM affect the quantity of mitochondria in equine oocytes. Oocytes were collected from the ovaries of slaughtered mares categorized as young (<12 years) or aged (≥12 years) and either denuded and prepared for analysis immediately (not-IVM) or matured in vitro for 30 hours before preparation (IVM). The mean oocyte mitochondrial DNA copy number was estimated by quantitative polymerase chain reaction and found to be significantly lower in oocytes from aged mares and that had been subjected to IVM than in any other group. Transmission electron microscopy demonstrated that mitochondria in aged mare oocytes subjected to IVM experienced significantly more swelling and loss of cristae than in other groups. We conclude that maternal aging is associated with a heightened susceptibility to mitochondrial damage and loss in equine oocytes, which manifests during IVM. This predisposition to mitochondrial degeneration probably contributes to reduced fertility in aged mares.     

Capacity of mouse oocytes from preantral follicles to undergo embryogenesis and development to live young after growth, maturation, and fertilization in vitro

A system is described here by which live mice can be produced from oocytes isolated from 12-day-old mice, be grown, matured, and fertilized in vitro, and then be transferred to pseudopregnant females. These oocytes were, at the time of isolation from preantral follicles, in about mid-growth phase and incompetent of undergoing germinal vesicle breakdown (GVB) without further development. The developmental competence of mouse oocytes that grew and underwent maturation in vitro was compared to oocytes that grew in vivo and underwent maturation in vitro. After isolation from mice 16 through 28 days old, oocytes were found to increase in size and to sequentially acquire the ability to undergo GVB, produce a polar body, cleave to the 2-cell stage after insemination, and develop to the blastocyst stage. Moreover, the number of cells per blastocyst increased with the age of the mice from which the immature oocytes were isolated. Oocyte-granulosa cell complexes isolated from 12-day-old mice were cultured for 10 days. At the end of the culture period, the oocytes had grown to a size equivalent to oocytes isolated from 16-day-old mice, and 87% of the in-vitro-grown (IVG) oocytes underwent GVB; 79% of these produced a clearly visible polar body when maturation occurred in the presence of follicle-stimulating hormone (FSH). The IVG oocytes cleaved to the 2-cell stage after insemination in vitro with a frequency equivalent to superovulated ova and ova that matured in vitro after isolation from 22-day-old mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytoplasmic maturation of cow oocytes cultured in vitro and their dehydrogenase activity]

Approximately in 80% of cow oocytes (n = 632) ended cytoplasmatic and nucleus maturation to the state of metaphase II in the conditions of 24 hours in vitro cultivation. In 300 oocytes cytochemically we have determined the activity of enzymes--the succinate dehydrogenase (SDH, EC 1.3.99.1.), alpha-glycerophosphate dehydrogenase (GPDH, EC 1.1.1.8.) and glucose-6-phosphate dehydrogenase (G6PDH, EC 1.1.1.49.). The reaction intensity of the observed dehydrogenases increased in cow oocytes which were cultivated in vitro for 24 hours. Dehydrogenases are located in the mitochondria which are laid out regularly in the cytoplasm of oocytes. Part of oocytes showed polarization in the lay out of reaction and part of oocytes gave extramitochondrial reaction.     

Male pronuclear formation and sperm mitochondria in porcine oocytes following intracytoplasmic injection of pig or mouse sperm

In the present study we determined the chromatin organization and fate of introduced mitochondria in porcine embryos following intracytoplasmic injection of pig or mouse sperm cells. At 3, 6, 9 and 12 h following injection of pig or mouse spermatozoa or isolated sperm heads, the oocytes were fixed and stained with propidium iodide. Between 3 and 6 h following injection, both porcine and murine sperm chromatin developed into pronuclei. The male and female pronuclei were apposed within 12 h in porcine oocytes following sperm injection from either source. We also introduced foreign mitochondria from either mouse or pig sperm midpiece into porcine oocytes following sperm injection. While porcine sperm mitochondria rapidly disappeared from the actively developing porcine oocytes, mouse sperm mitochondria remained in the embryos until the 8-cell stage. These results suggest that pronuclear formation and movement occur between 6 and 12 h following sperm incorporation into the cytoplasm, and that foreign mitochondria are selectively removed in a species-specific manner.     

AN ELECTRON MICROSCOPE STUDY OF RADIATION DAMAGE IN THE MOUSE OOCYTE

Cytological changes occurring in young oocytes of the mouse, following whole-body x-irradiation, have been examined by light and electron microscopy. Two minutes after a dose of 200 r, a drop occurs in the number of mitochondria per oocyte. The normal number of mitochondria is restored in the next few minutes. Five to 6 hours after a dose of 7 r, and 30 to 45 minutes following a dose of 200 r, all the oocytes are markedly contracted. In the next 2 hours (at a dose of 7 r), some cells shrink further and become pycnotic, while others expand and show signs of karyolysis. Of the expanded cells, some (about 50 per cent of total young oocytes) become morphologically normal. In both pycnotic and karyolytic nuclei, the nucleolus was contracted but without loss of its fibrillar structure. The contracted nucleolus appeared similar to those seen in some nearly mature normal oocytes (these oocytes have a high natural death rate). No other cell type in the ovary was affected by doses of x-rays up to 200 r. Observations on the nucleus of the normal oocyte are included. In the dictyate stage of meiotic prophase the chromosomes were dispersed into bundles of 100 A microfibrils. The main component of the nucleolus was found to be tightly coiled fibrils of 60 to 100 A, which appear to have a close relationship with the microfibrils of the chromosomes.     

In vivo studies on the incorporation of microinjected acidic proteins of the large ribosomal subunit from Escherichia coli and artermia salina into oocyte ribosomes from Xenopus laevis.

Tritium-labeled acidic proteins from the large ribosomal subunit of Artermia salina or Escherichia coli were microinjected into the cytoplasm of stage IV/V oocytes from Xenopus laevis. eL12 from the large ribosomal subunit of A. salina but not L7/L12 or L7/L12--L10 from E. coli is specifically incorporated into 60S ribosomal subunits of oocytes. This incorporation is not significantly inhibited by actinomycin D. Incorporation of eL12 into the 60S subunits occurs in enucleated oocytes, suggesting that active ribosomal ribonucleic acid synthesis and ribosome assembly as well are not prerequired for this reaction. Apparently the incorporation proceeds via an exchange reaction between a free cytoplasmic pool of eL12 and ribosomal eL12.     

Stereological analysis of mitochondria in embryos of Rana temporaria and Bufo bufo during cleavage

Total numbers of mitochondria and their morphology have been quantitatively determined in mature oocytes and in cleaving embryos of two anuran species Rana temporaria and Bufo bufo using stereological methods. Surface densities of inner mitochondrial membranes for both studied species during cleavage ranged from 5.43 m2/cm3 to 7.53 m2/cm3, whereas volume densities of mitochondria did not exceed 1.65%. Since values of these parameters were low, thus embryos during cleavage may be considered as metabolically "silent". Transition of ultrastructural morphology of mitochondria towards that characterising actively respiring organelles occurs at stage 9 for R. temporaria and at stage 8 for B. bufo, correlated with blastula-gastrula and mid-blastula transition, respectively. The total numbers of mitochondria N(c) in mature oocytes are as high as 114.8 and 107.2 millions for R. temporaria and B. bufo, respectively, and during cleavage at late blastula stages they increase to 300 millions for both species under study. We suggest that an undefined mechanism might eliminate during cleavage those amphibian embryos which contain small number of mitochondria and low levels of nutrient substances.     

Developmental capacity of mouse oocytes matured in vitro: effects of gonadotrophic stimulation, follicular origin and oocyte size.

Development of mammalian oocytes is usually correlated with ovarian follicular development. This correlation was tested by determining whether gonadotrophic stimulation of follicular development in immature mice resulted in a coordinated increase in the embryonic developmental capacity of the oocytes. Oocyte cumulus cell complexes were isolated at the germinal vesicle stage from small, medium and large antral follicles of 26-day-old mice and matured and fertilized in vitro. The frequency with which embryos from oocytes from small follicles completed the two-cell to blastocyst transition was lower than for embryos from oocytes from large follicles (33% and 79%, respectively). Germinal-vesicle stage oocyte-cumulus cell complexes were isolated from 22-26-day-old mice that were unprimed or primed by injection of equine chorionic gonadotrophin 48 h before isolation. Oocytes were matured in control medium, or in medium containing 1 microgram follicle-stimulating hormone (FSH) ml-1, and then fertilized in vitro. Priming did not increase the number of embryos completing the two-cell stage to blastocyst transition in the 22-day-old group nor did FSH treatment of maturing oocytes when the oocytes were isolated from unprimed 22-day-old mice. In contrast, priming increased the percentage of embryos completing the two-cell stage to blastocyst transition in the 26-day-old group by 20%. FSH treatment of maturing oocytes from the unprimed, 26-day-old group increased the number of embryos completing the transition to the same level as those in the primed 26-day-old group, but FSH did not increase the frequency of transition in the primed 26-day-old group.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of hypoxanthine on mouse oocyte growth and development in vitro: maintenance of meiotic arrest and gonadotropin-induced oocyte maturation

The concentration of hypoxanthine in mouse follicular fluid has been estimated to be 2-4 mM, and although this concentration maintains meiotic arrest in fully grown mouse oocytes in vitro, oocyte maturation in vivo is not induced by a decrease in the concentration of this purine in follicular fluid (J. J. Eppig, P. F. Ward-Bailey, and D. L. Coleman, Biol. Reprod. 33, 1041-1049, 1985). In the present study, the effect of 2 mM hypoxanthine on oocyte growth and development in vitro was assessed and the ability of gonadotropins to stimulate oocyte maturation in the continued presence of hypoxanthine was determined. Oocyte-granulosa cell complexes were isolated from 10- to 11-day-old mice and cultured in the presence or absence of 2 mM hypoxanthine. Oocytes from 10- to 11-day-old mice are in mid-growth phase and, without further development, are incompetent of undergoing meiotic maturation. During a 12-day culture period the granulosa cell-enclosed oocytes approximately doubled in size and, regardless of the presence or absence of hypoxanthine, 50-70% developed competence to undergo germinal vesicle breakdown (GVBD). Hypoxanthine promoted the continued association of oocytes with their companion granulosa cells during the 12-day culture period, and therefore had a beneficial effect on oocyte development. Most of the oocytes that acquired GVBD competence in the absence of hypoxanthine underwent spontaneous GVBD. In contrast, 95% of the GVBD-competent oocytes were maintained in meiotic arrest by hypoxanthine. Following withdrawal of the hypoxanthine after the 12-day culture, 75% of the GVBD-competent oocytes underwent GVBD. These results show that hypoxanthine, and/or its metabolites, maintains meiotic arrest in oocytes that grow and acquire GVBD competence in vitro. Follicle-stimulating hormone (FSH), but not luteinizing hormone or human chorionic gonadotropin, induced oocyte GVBD in the continued presence of hypoxanthine. FSH stimulated oocyte maturation at a significantly (P less than 0.01) higher frequency than coculture of the granulosa cell-denuded oocytes with granulosa cells in the continued presence of hypoxanthine. FSH did not induce the maturation of denuded oocytes cocultured with granulosa cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

The fine structure of mitochondria and the mitochondrial cloud during oogenesis on the sea anemone Actinia

The appearance and arrangement of the mitochondria during all stages of oocyte growth in the sea anemone Actinia fragacea (Cnidaria: Anthozoa) have been examined by electron microscopy. In small oocytes, the mitochondria are generally squat, with a dense matrix and numerous cristae, although a proportion may show an unusual arrangement of prismatic cristae. During early oogenesis, the mitochondria tend to be arranged in aggregates rather than randomly scattered, and may be associated with nuage material. With the onset of vitellogenesis, a large mitochondrial aggregate forms next to the nucleus. During early vitellogenesis this aggregate enlarges and comes to resemble the mitochondrial clouds found in some amphibian oocytes. Within the cloud, many mitochondria appear to be highly elongate and irregular in shape. The cloud begins to fragment and disperse midway through vitellogenesis at about the time when cortical granules appear. In fully grown oocytes, some mitochondria may have a much less dense matrix and fewer cristae than the remainder, which may be related to their state of activity.     

Protein kinase C activity regulates the onset of anaphase I in mouse oocytes

The metaphase-to-anaphase I transition is a key step in the completion of meiosis I. In mouse oocytes, competence to exit metaphase I (MI) is developmentally regulated and typically not acquired until the preovulatory stage. The possible role of protein kinase C (PKC) in regulating this critical transition was assessed in both normal oocytes isolated from small antral follicles (18-day-old B6SJLF1 mice), which have not yet developed the capacity to progress to metaphase II (MII), and also oocytes defective in their ability to exit MI despite development to the preovulatory stage (24-day-old CX8 recombinant inbred strains). In both systems, transient suppression of endogenous PKC activity by treatment with a PKC-specific inhibitor, bisindolylmaleimide I (BIM), promoted the onset of anaphase I in a dose-dependent manner, while activation of PKC with the phorbol ester TPA blocked progression to MII. Following a 2-h incubation with BIM, the majority of oocytes progressed to, and arrested at, MII. The resulting MII oocytes were fertilizable in vitro, showing similar cleavage and blastocyst development rates between BIM treated and untreated controls. Transferred embryos resulted in the development of pups to term in both groups. These data demonstrate that PKC plays an important role in regulating the onset of anaphase I in mouse oocytes. Moreover, it is concluded that oocytes isolated from small antral follicles become blocked at MI due to a PKC-mediated signal, suggesting that acquisition of competence to complete meiosis I involves, in part, the control of PKC activity. Similarly, failure to regulate PKC activity at the preovulatory stage likely promotes arrest at MI.     

"两步法"体外培养山羊卵母细胞的超微结构观察

有假说认为,卵母细胞在体外培养过程中,如果延长GV期,可促进卵母细胞进一步成熟,因而提高发育潜能。采用山羊半卵泡和卵母细胞共培养,抑制卵母细胞GVBD发生,从而延长GV期。比较了共培养前后和恢复成熟培养后卵母细胞的超微结构变化,其目的从亚细胞水平寻找卵母细胞进一步成熟的证据。研究发现,常规成熟培养:有卵周隙存在,但不贯通,局部区域卵膜与透明带结合紧密;部分皮质区尚有细胞器存在;微绒毛大部分从透明带中撤出,倒伏于质膜表面,数量较多,形态较为粗大;皮层颗粒质膜下部分单层分布,部分散布于皮质区;线粒体均匀散布于卵质中央区。共培养前:卵母细胞的卵周隙尚未形成,微绒毛没有从透明带中撤出;线粒体等细胞器分布于皮质区,皮层颗粒成簇状分布,皮质区富含细胞器。共培养后:局部形成卵周隙,微绒毛已自透明带中撤出,数量较多,垂直或倒伏于卵膜表面;线粒体以簇状分批开始内移,皮层颗粒已部分单层分布于质膜下,部分皮质区缺乏细胞器。恢复成熟培养后:卵周隙进一步扩大并且贯通,微绒毛数量减少并且绝大多数垂直于卵膜;线粒体在卵质中央区均匀分布,皮层颗粒卵膜下单层分布,大部分皮质区无细胞器存在。利用“两步法”培养得到的卵母细胞与体外常规成熟培养的卵母细胞相比,更有利于皮层颗粒的质膜下单层分布,卵母细胞卵周隙的形成与贯通,微绒毛数量减少和垂直于卵膜表面,无细胞器皮层区的进一步形成。因此,更有利于卵母细胞胞质的进一步成熟。     

Oogenesis of Tilapia mossambica. III. The cytoplasm of previtellogenic oocytes]

Using methods of light and electron microscopy and of autoradiography, the morphology of cytoplasm in previtellogenic oocytes of tilapia mossambique was studied. Similar to other bony fishes, mitochondria at the early previtellogenic oocytes are mostly located in the perinuclear cytoplasm to be later distributed over the whole volume of growing oocytes. The Golgi complex is poorly developed. In the peripheral regions of the late previtellogenic oocytes, stickform mitochondria, pinocytotic vesicles and microvilli are observed, along with the perioocyte space formation. In the cytoplasm of previtellogenic oocytes polyribosomes appear. No differences in 3H-leucine incorporation intensity was noticed in oocytes of different previtellogenic stages. The characteristic feature of tilapia mossambique previtellogenic oocytes, in comparison with other bony fishes, is the presence of fat droplets in their cytoplasm.     

Possible participation of mitochondria in lipid yolk formation in oocytes of paddlefish and sturgeon

The ovary of paddlefish and sturgeons (Acipenseriformes) is composed of discrete units: the ovarian nests and ovarian follicles. The ovarian nests comprise oogonia and numerous early dictyotene oocytes surrounded by somatic prefollicular cells. Each ovarian follicle consists of a spherical oocyte and a layer of follicular cells situated on a thick basal lamina, encompassed by thecal cells. The cytoplasm of previtellogenic oocytes is differentiated into two distinct zones: the homogeneous and granular zones. The homogeneous cytoplasm is organelle-free, whereas the granular cytoplasm contains numerous organelles, including mitochondria and lipid droplets. We have analyzed the cytoplasm of early dictyotene and previtellogenic oocytes ultrastructurally and histologically. In the cytoplasm of early dictyotene oocytes, two morphologically different types of mitochondria can be distinguished: (1) with well-developed cristae and (2) with distorted and fused cristae. In previtellogenic oocytes, the mitochondria of the second type show various stages of cristae distortion; they contain and release material morphologically similar to that of lipid droplets and eventually degenerate. This process of mitochondrial transformation is accompanied by an accumulation of lipid droplets that form a single large accumulation (lipid body) located in the vicinity of the oocyte nucleus (germinal vesicle). The lipid body eventually disperses in the oocyte center. The possible participation of these mitochondria in the formation of oocyte lipid droplets is discussed. This work was supported by funds from the research grant BW/IZ/2005 to M.Ż. An erratum to this article can be found at http://dx.doi.org/. An erratum to this article can be found at     

The site of the acrosome reaction during in vivo penetration of the sheep oocyte

In vivo fertilization of sheep eggs has been studied by electron microscopy. Remnants of the acrosome reaction were present at the zona surface of every penetrated egg, indicating that the acrosome reaction in sheep occurs at the surface of the zona pellucida. To determine whether follicular oocytes could specifically bind spermatozoa, oocytes isolated from different size classes of antral follicles were transferred into the oviducts of mated ewes, recovered 4 hr 30 min later, and analyzed by electron microscopy. Oocytes from follicles up to 1 mm in diameter failed to bind spermatozoa and were not penetrated. In contrast, the zona of oocytes from follicles ? 2 mm in diameter induced the acrosome reaction. These oocytes were penetrated but failed to achieve cortical granule exocytosis and so to mount a block to polyspermy. Moreover, sperm nuclei incorporated into the ooplasm did not decondense although the sperm nuclear envelope was dispersed.     

THE ORIGIN OF PROTEIN AND FATTY YOLK IN RANA PIPIENS : I. Phase Microscopy

Study of living frog oocytes with the phase microscope has shown that the early yolk appears in two forms. One of these, the protein yolk, consists of thin, dense, plate-like bodies which in face view are almost always regular hexagons. The other form, the fatty yolk, occurs as clusters of globules of varying sizes. The plate-like bodies occur both singly and in clusters. As the oocytes mature these plate-like bodies grow in size while retaining their hexagonal outline. Mitochondria have been observed to increase in length and numbers as the oocytes mature; they are rods or filaments at all stages of growth up to an oocyte diameter of 300 microns. The oocyte cytoplasm gradually becomes packed with long mitochondria, plate-like bodies, and clusters of globules.     

The effect of aluminium on respiration of wheat roots

The effects of aluminium ions on respiration of excised root apices from wheat (Triticum aestivum L. cv. Vulcan) and on isolated mitochondria have been investigated. Addition of 75μ M aluminium to the growth medium of 4-day-old seedlings inhibited O₂ uptake by excised root apices by 23 and 35% after 12 and 24 h, respectively. This decreased rate of respiration was initially caused by inhibition of the cytochrome pathway of mitochondrial electron transport. The cyanide-insensitive, alternative pathway was inhibited only after more prolonged exposure to aluminium. Mitochondria isolated from roots of aluminium-treated seedlings had reduced oxidative capacity with substrates that supply electrons to Complexes I and II, compared with mitochondria from roots of untreated control seedlings. The state 3 and state 4 rates of O₂ uptake and the uncoupled rates with these substrates were also inhibited when aluminium was added directly to reaction mixtures containing mitochondria isolated from untreated plants. In contrast, when aluminium was added to reaction mixtures oxidizing exogenous NADH, state 4 O₂ uptake was stimulated, whereas no effect was observed on the state 3 rate or the rate in the presence of uncoupler. The results suggest that aluminium initially affects electron flow through Complexes I and II, and that after more prolonged exposure, aluminium may also interact with other sites in mitochondria.     

Supplementation of mitochondria from endometrial mesenchymal stem cells improves oocyte quality in aged mice

Maternal ageing is one of the major causes of reduced ovarian reserve and low oocyte quality in elderly women. Decreased oocyte quality is the main cause of age‐related infertility. Mitochondria are multifunctional energy stations that determine the oocyte quality. The mitochondria in aged oocytes display functional impairments with mtDNA damage, which leads to reduced competence and developmental potential of oocytes. To improve oocyte quality, mitochondrial supplementation is carried out as a potential therapeutic approach. However, the selection of suitable cells as the source of mitochondria remains controversial. We cultivated endometrial mesenchymal stem cells (EnMSCs) from aged mice and extracted mitochondria from EnMSCs. To improve the quality of oocytes, GV oocytes were supplemented with mitochondria via microinjection. And MII oocytes from aged mice were fertilized by intracytoplasmic sperm injection (ICSI), combining EnMSCs'' mitochondrial microinjection. In this study, we found that the mitochondria derived from EnMSCs could significantly improve the quality of aged oocytes. Supplementation with EnMSC mitochondria significantly increased the blastocyst ratio of MII oocytes from aged mice after ICSI. We also found that the birth rate of mitochondria‐injected ageing oocytes was significantly increased after embryo transplantation. Our study demonstrates that supplementation with EnMSC‐derived mitochondria can improve the quality of oocytes and promote embryo development in ageing mice, which might provide a prospective strategy for clinical treatment.

In this study, we chose endometrial mesenchymal stem cells (EnMSCs) as the sources of mitochondria. We isolated the EnMSCs from 10‐month‐old mice and then extracted the mitochondria of EnMSCs. Then, the GV oocytes and MII oocytes from aged mice were injected with mitochondria. We found that mitochondria derived from EnMSCs could significantly improve the quality of oocytes, promote the embryonic development and improve the birth rates of aged mice.     

Microinjection of cytoplasm or mitochondria derived from somatic cells affects parthenogenetic development of murine oocytes

Cloned mammals are readily obtained by nuclear transfer using cultured somatic cells; however, the rate of generating live offspring from the reconstructed embryos remains low. In nuclear transfer procedures, varying quantities of donor cell mitochondria are transferred with nuclei into recipient oocytes, and mitochondrial heteroplasmy has been observed. A mouse model was used to examine whether transferred mitochondria affect the development of the reconstructed oocytes. Cytoplasm or purified mitochondria from somatic cells derived from the external ear, skeletal muscle, and testis of Mus spretus mice or cumulus cells of Mus musculus domesticus mice were transferred into M. m. domesticus (B6SJLF1 and B6D2F1) oocytes to observe parthenogenetic development through the morula stage. All B6D2F1 oocytes injected with somatic cytoplasm or mitochondria showed delayed development when compared to oocytes injected with buffer. The developmental rates were not different among injected cell sources, with the exception of testis-derived donor cells injected into B6SJLF1 oocytes (P < 0.01). The developmental rate of B6D2F1 oocytes injected with buffer alone (98.8% survival) was different from those injected with somatic cytoplasm (60.8% survival) or somatic mitochondria (56.5% survival) (P < 0.01). Conversely, injection of ooplasm into B6D2F1 oocytes did not affect parthenogenetic development (100% survival). Our results indicate that injection of somatic cytoplasm or mitochondria affected parthenogenetic development of murine oocytes. These results have further implications for in vitro fertilization protocols employing ooplasmic transfer where primary oocyte failure is not confirmed.