Sperm Mitochondria in Reproduction： Good or Bad and Where Do They Go？

The mitochondrion is the major energy provider to power sperm motility. In mammals, aside from the nuclear genome, mitochondrial DNA （mtDNA） also contributes to oxidative phosphorylation to impact production of ATP by coding 13 polypeptides. However, the role of sperm mitochondria in fertilization and its final fate after fertilization are still controversial. The viewpoints that sperm bearing more mtDNA will have a better fertilizing capability and that sperm mtDNA is actively eliminated during early embryogenesis are widely accepted. However, this may be not true for several mammalian species, including mice and humans. Here, we review the sperm mitochondria and their mtDNA in sperm functions, and the mechanisms of maternal mitochondrial inheritance in mammals.     

Cellular promiscuity: explaining cellular fidelity in vivo against unrestrained pluripotency in vitro

The differentiation of pluripotent stem cells into various progeny is perplexing. In vivo, nature imposes strict fate constraints. In vitro, PSCs differentiate into almost any phenotype. Might the concept of ‘cellular promiscuity'' explain these surprising behaviours?John Gurdon''s [1] and Shinya Yamanaka''s [2] Nobel Prize involves discoveries that vex fundamental concepts about the stability of cellular identity [3,4], ageing as a rectified path and the differences between germ cells and somatic cells. The differentiation of pluripotent stem cells (PSCs) into progeny, including spermatids [5] and oocytes [6], is perplexing. In vivo, nature imposes strict fate constraints. Yet in vitro, reprogrammed PSCs liberated from the body government freely differentiate into any phenotype—except placenta—violating even somatic cell against germ cell segregations. Albeit that it is anthropomorphic, might the concept of ‘cellular promiscuity'' explain these surprising behaviours?Fidelity to one''s differentiated state is nearly universal in vivo—even cancers retain some allegiance. Appreciating the mechanisms in vitro that liberate reprogrammed cells from the numerous constraints governing development in vivo might provide new insights. Similarly to highway guiderails, a range of constraints preclude progeny cells within embryos and organisms from travelling too far away from the trajectory set by their ancestors. Restrictions are imposed externally—basement membranes and intercellular adhesions; internally—chromatin, cytoskeleton, endomembranes and mitochondria; and temporally by ageing.‘Cellular promiscuity'' was glimpsed previously during cloning; it was seen when somatic cells successfully ‘fertilized'' enucleated oocytes in amphibians [1] and later with ‘Dolly'' [7]. Embryonic stem cells (ESCs) corroborate this. The inner cell mass of the blastocyst cells develops faithfully, but liberation from the trophoectoderm generates pluripotent ESCs in vitro, which are freed from fate and polarity restrictions. These freedom-seeking ESCs still abide by three-dimensional rules as they conform to chimaera body patterning when injected into blastocysts. Yet if transplanted elsewhere, this results in chaotic teratomas or helter-skelter in vitro differentiation—that is, pluripotency.August Weismann''s germ plasm theory, 130 years ago, recognized that gametes produce somatic cells, never the reverse. Primordial germ cell migrations into fetal gonads, and parent-of-origin imprints, explain how germ cells are sequestered, retaining genomic and epigenomic purity. Left uncontaminated, these future gametes are held in pristine form to parent the next generation. However, the cracks separating germ and somatic lineages in vitro are widening [5,6]. Perhaps, they are restrained within gonads not for their purity but to prevent wild, uncontrolled misbehaviours resulting in germ cell tumours.The ‘cellular promiscuity'' concept regarding PSCs in vitro might explain why cells of nearly any desired lineage can be detected using monospecific markers. Are assays so sensitive that rare cells can be detected in heterogeneous cultures? Certainly population heterogeneity is considered for transplantable cells—dopaminergic neurons and islet cells—compared with applications needing few cells—sperm and oocytes. This dilemma of maintaining cellular identity in vitro after reprogramming is significant. If not addressed, the value of unrestrained induced PSCs (iPSCs) as reliable models for ‘diseases in a dish'', let alone for subsequent therapeutic transplantations, might be diminished. X-chromosome re-inactivation variants in differentiating human PSCs, epigenetic imprint errors and copy number variations are all indicators of in vitro infidelity. PSCs, which are held to be undifferentiated cells, are artefacts after all, as they undergo their programmed development in vivo.If correct, the hypothesis accounts for concerns raised about the inherent genomic and epigenomic unreliability of iPSCs; they are likely to be unfaithful to their in vivo differentiation trajectories due to both the freedom from in vivo developmental programmes, as well as poorly characterized modifications in culture conditions. ‘Memory'' of the PSC''s identity in vivo might need to be improved by using approaches that might not fully erase imprints. Regulatory authorities, including the Food & Drug Administration, require evidence that cultured PSCs do retain their original cellular identity. Notwithstanding fidelity lapses at the organismal level, the recognition that our cells have intrinsic freedom-loving tendencies in vitro might generate better approaches for only partly releasing somatic cells into probation, rather than full emancipation.     

Protein profile changes during porcine oocyte aging and effects of caffeine on protein expression patterns

It has been shown that oocyte aging critically affects reproduction and development. By using proteomic tools, in the present study, changes in protein profiles during porcine oocyte aging and effects of caffeine on oocyte aging were investigated. By comparing control MII oocytes with aging MII oocytes, we identified 23 proteins that were up-regulated and 3 proteins that were down-regulated during the aging process. In caffeine-treated oocytes, 6 proteins were identified as up-regulated and 12 proteins were identified as down-regulated. A total of 38 differentially expressed proteins grouped into 5 regulation patterns were determined to relate to the aging and anti-aging process. By using the Gene Ontology system, we found that numerous functional gene products involved in metabolism, stress response, reactive oxygen species and cell cycle regulation were differentially expressed during the oocyte aging process, and most of these proteins are for the first time reported in our study, including 2 novel proteins. In addition, several proteins were found to be modified during oocyte aging. These data contribute new information that may be useful for future research on cellular aging and for improvement of oocyte quality.     

Common ancestry of iron oxide- and iron-sulfide-based biomineralization in magnetotactic bacteria

Magnetosomes are prokaryotic organelles produced by magnetotactic bacteria that consist of nanometer-sized magnetite (Fe₃O₄) or/and greigite (Fe₃S₄) magnetic crystals enveloped by a lipid bilayer membrane. In magnetite-producing magnetotactic bacteria, proteins present in the magnetosome membrane modulate biomineralization of the magnetite crystal. In these microorganisms, genes that encode for magnetosome membrane proteins as well as genes involved in the construction of the magnetite magnetosome chain, the mam and mms genes, are organized within a genomic island. However, partially because there are presently no greigite-producing magnetotactic bacteria in pure culture, little is known regarding the greigite biomineralization process in these organisms including whether similar genes are involved in the process. Here using culture-independent techniques, we now show that mam genes involved in the production of magnetite magnetosomes are also present in greigite-producing magnetotactic bacteria. This finding suggest that the biomineralization of magnetite and greigite did not have evolve independently (that is, magnetotaxis is polyphyletic) as once suggested. Instead, results presented here are consistent with a model in which the ability to biomineralize magnetosomes and the possession of the mam genes was acquired by bacteria from a common ancestor, that is, the magnetotactic trait is monophyletic.     

The movements and fusion of the pronuclei at fertilization of the sea urchin Lytechinus variegatus: Time-lapse video microscopy

The penetration of the sperm into the egg, and the movements of the male and female pronuclei were followed from sperm attachment through pronuclear fusion, using time-lapse video microscopy of gametes and zygotes of the sea urchin Lytechinus variegatus (23° C). The pronuclei move in four stages: I. Sperm Entry Phase, following sperm-egg fusion and a rapid radiating surface contraction (5.9 ± 1.3 μm/second) when egg microvilli engulf the sperm head, midpiece, and tail to form the fertilization cone and the sperm tail beats in the egg cytoplasm; II. Formation of the Sperm Aster, which pushes the male pronucleus centripetally at a rate of 4.9 ± 1.7 μm/minute starting 4.4 ± 0.5 minutes after sperm-egg fusion, as the male pronucleus undergoes chromatin decondensation; III. Movement of the Female Pronucleus, the greatest and fastest of the pronuclear motions at a rate of 14.6 ± 3.5 μm/minute at 6.8 ± 1.2 minute after sperm-egg fusion, which establishes the contact between the pronuclei; and IV. Centration of the Pronuclei to the egg center at a rate of 2.6 ± 0.9 μm/minute by 14.1 ± 2.6 minutes after sperm-egg fusion. Pronuclear fusion typically occurs after stage IV and proceeds rapidly starting 14.7 ± 3.6 minutes after sperm-egg fusion with the male pronucleus coalescing into the female pronucleus at a rate of 14.2 ± 2.6 μm/minute.     

Intracellular pH shift leads to microtubule assembly and microtubule-mediated motility during sea urchin fertilization: correlations between elevated intracellular pH and microtubule activity and depressed intracellular pH and microtubule disassembly

The regulation of the microtubule-mediated motions within eggs during fertilization was investigated in relation to the shift in intracellular pH (pHi) that occurs during the ionic sequence of egg activation in the sea urchins Lytechinus variegatus and Arbacia punctulata. Microtubule assembly during formation of the sperm aster and mitotic apparatus was detected by anti-tubulin immunofluorescence microscopy, and the microtubule-mediated migrations of the sperm and egg nuclei were studied with time-lapse video differential interference contrast microscopy. Manipulations of intracellular pH were verified by fluorimetric analyses of cytoplasmic fluorescein incorporated as fluorescein diacetate. The ionic sequence of egg activation was manipulated i) to block the pHi shift at fertilization or reduce the pHi of fertilized eggs to unfertilized values, ii) to elevate artificially the pHi of unfertilized eggs to fertilized values, and iii) to elevate artificially or permit the normal pHi shift in fertilized eggs in which the pHi shift at fertilization was previously prevented. Fertilized eggs in which the pHi shift was suppressed did not assemble microtubules or undergo the normal microtubule-mediated motions. In fertilized eggs in which the pHi was reduced to unfertilized levels after the assembly of the sperm aster, no motions were detected. If the intracellular pH was later permitted to rise, normal motile events leading to division and development occurred, delayed by the time during which the pH elevation was blocked. Microtubule-mediated events occurred in eggs in which the intracellular pH was elevated, even in unfertilized eggs in which the pH was artificially increased. These results indicate that the formation and normal functioning of the egg microtubules is initiated, either directly or indirectly, by the shift in intracellular pH that occurs during fertilization.     

Polo-like kinase-1 in porcine oocyte meiotic maturation, fertilization and early embryonic mitosis.

Polo-like kinases (Plks) are a family of serine/threonine protein kinases that regulate multiple stages of mitosis. Expression and distribution of polo-like kinase 1 (Plk1) were characterized during porcine oocyte maturation, fertilization and early embryo development in vitro, as well as after microtubule polymerization modulation. The quantity of Plk1 protein remained stable during meiotic maturation. Plk1 accumulated in the germinal vesicles (GV) in GV stage oocytes. After germinal vesicle breakdown (GVBD), Plk1 was localized to the spindle poles at metaphase I (MI) stage, and then translocated to the middle region of the spindle at anaphase-telophase I. Plk1 was also localized in MII spindle poles and on the spindle fibers and on the middle region of anaphase-telophase II spindles. Plk1 was not found in the spindle region when colchicine was used to inhibit microtubule organization, while it accumulated as several dots in the cytoplasm after taxol treatment. After fertilization, Plk1 concentrated around the female and male pronuclei. During early embryo development, Plk1 was found to be in association with the mitotic spindle at metaphase, but distributed diffusely in the cytoplasm at interphase. Our results suggest that Plk1 is a pivotal regulator of microtubule organization and cytokinesis during porcine oocyte meiotic maturation, fertilization, and early embryo cleavage in pig oocytes.     

Evaluation of the Inheritance of the Complex Vertebral Malformation Syndrome by Breeding Studies

To investigate the congenital complex vertebral malformation syndrome (CVM) in Holstein calves, two breeding studies were performed including 262 and 363 cows, respectively. Cows were selected from the Danish Cattle Database based on pedigree and insemination records. Selected cows were progeny of sires with an established heterozygous CVM genotype and pregnant after insemination with semen from another sire with heterozygous CVM genotype. Following calving the breeders should state, if the calf was normal and was requested to submit dead calves for necropsy. In both studies, significantly fewer CVM affected calves than expected were obtained; a finding probably reflecting extensive intrauterine mortality in CVM affected foetuses. The findings illustrate increased intrauterine mortality as a major potential bias in observational studies of inherited disorders.     

In vivo and in vitro characterization of novel microparticulates based on hyaluronan and chitosan hydroglutamate

This study examined the application of previously characterized microparticles composed of hyaluronan (HA) and chitosan hydroglutamate (CH) as well as novel microparticles consisting of both polymers (HA/CH) to improve the nasal delivery of a model drug. The rabbit bioavailabilities of gentamicin incorporated in HA, CH, and HA/CH microparticles were increased 23-, 31-, and 42-fold, respectively, compared with the control intranasal solution of gentamicin, indicating that all test microparticles were retained for longer periods on the nasal mucosa of the rabbits as supported by previous in vitro dissolution as well as frog palate mucoadhesion studies, thereby improving drug absorption. The higher bioavailabilities of CH-based formulations (CH and HA/CH) suggest the penetration-enhancing effects of CH may also be partially responsible for the improvement. A model was developed, based on a glass impinger device, to deliver dry powder formulations reproducibly onto the surface of cultured cell monolayers. In vitro permeability and fluorescence microscopy studies on the tight junctions of the 16HBE14o- cell lines further confirmed the ability of CH-based formulations to enhance penetration. Furthermore, the in vitro absorption profile from cell culture studies was consistent with those determined from in vivo studies. The complementary effect from the mucoadhesive nature of HA coupled with the penetration-enhancing effects of CH makes the novel HA/CH formulation a promising nasal delivery system.