Barbara Durrant

Comparison of Glycolysis and Oxidative Phosphorylation as Energy Sources for Mammalian Sperm Motility, Using the Combination of Fluorescence Imaging, Laser Tweezers, and Real-Time Automated Tracking and Trapping

The combination of laser tweezers, fluorescent imaging, and real‐time automated tracking and trapping (RATTS) can measure sperm swimming speed and swimming force simultaneously with mitochondrial membrane potential (MMP). This approach is used to study the roles of two sources of ATP in sperm motility: oxidative phosphorylation, which occurs in the mitochondria located in the sperm midpiece and glycolysis, which occurs along the length of the sperm tail (flagellum). The relationships between (a) swimming speed and MMP and (b) swimming force and MMP are studied in dog and human sperm. The effects of glucose, oxidative phosphorylation inhibitors and glycolytic inhibitors on human sperm motility are examined. The results indicate that oxidative phosphorylation does contribute some ATP for human sperm motility, but not enough to sustain high motility. The glycolytic pathway is shown to be a primary source of energy for human sperm motility. J. Cell. Physiol. 217: 745–751, 2008.

Pseudogenes in ribonuclease evolution" a source of new biomacromolecular function?

Bovine seminal ribonuclease (RNase) diverged from pancreatic RNase after a gene duplication ca. 35 million years ago. Members of the seminal RNase gene family evidently remained as unexpressed pseudogene for much of its evolutionary history. Between 5 and 10 million years ago, however, after the divergence of kudu but before the divergence of ox, evidence suggests that the pseudogene was repaired and expressed. Intriguingly, detailed analysis of the sequences suggests that the repair may have involved gene conversion, transfer of information from the pancreatic gene to the RNase pseudogene. Further, the ratio of non‐silent to silent substitutions suggests that the pancreatic RNases are divergently evolving under functional constraints, the seminal RNase pseudogenes are diverging under no functional constraints, while the genes expressed in the seminal plasma are evolving extremely rapidly in their amino acid sequences, as if to fulfil a new physiological role.

In vitro maturation of bitch oocytes from advanced preantral follicles in synthetic oviduct fluid medium: serum is not essential

The ability of oocytes from preantral follicles to mature in vitro was assessed using a synthetic oviduct fluid (SOF) medium. Advanced preantral follicles (approximately 210 microm diameter) were isolated from the ovaries of domestic bitches and assigned to one of four treatment groups: (1) SOF (n = 230); (2) SOF + 3 mg/ml bovine serum albumin (+BSA, n = 220); (3) SOF + 20% fetal bovine serum (+FBS, n = 227); or (4) SOF + 3 mg/ml BSA + 20% FBS (+BSA+FBS, n = 232), then cultured for up to 72 h. A group of control follicles was not cultured (n = 103). The percentages of oocytes reaching metaphase I to metaphase II stages (MI to MII) did not differ between treatments at each culture period. Within treatments, the percentages of oocytes at MI to MII stages did not differ with duration of culture. However, when compared to the control group (0.97%) the percentages of oocytes at MI to MII increased (P < 0.05) in the SOF group after 48 h (10.0%) and 72 h (12.2%) of culture. In the +BSA (10.1%) and +FBS (9.7%) groups, the percentages of oocytes at MI to MII increased (P < 0.05) above control values only after 72 h of culture. The percentage of oocytes at MI to MII did not significantly increase in the +BSA+FBS group (3.9,6.6 and 7.6% at 24,48 and 72 h of culture, respectively) compared to the control group. These results indicate that under the described conditions supplementation of culture medium with BSA or FBS is not essential, and the simple medium SOF can support nuclear maturation of a small proportion of bitch oocytes in vitro.

IN VITRO MATURATION OF DOMESTIC DOG OOCYTES CULTURED IN ADVANCED PREANTRAL AND EARLY ANTRAL FOLLICLES

Initial studies in our laboratory demonstrated that a large proportion of domestic dog advanced preantral (APAN) and early antral (EAN) follicles contained grown oocytes that had acquired the dense cytoplasmic lipid characteristic of preovulatory oocytes. The objective of this study was to assess nuclear maturation of those oocytes after in vitro culture. Both APAN and EAN follicles (152 to 886 microns in diameter) were isolated from ovaries by treatment with collagenase and DNase. The follicles were cultured in Dulbeccos Modified Eagles medium/nutrient mixture F-12 Ham culture medium supplemented with 20% (v/v) fetal bovine serum (FBS), 2 mM L-glutamine, 1% (v/v) antibiotic-antimycotic, 1 microgram FSH/ml, 10 IU hCG/ml and 1 microgram estradiol/ml. Within each group (APAN or EAN), control follicles were not cultured (0 h), and 2 to 12 follicles per well were incubated under a humidified atmosphere of 5% CO2 in air at 37 degrees C for 24, 48 or 72 h. After 24 h of culture, significantly more (5.3%, 20/374; P < 0.05) oocytes from APAN follicles reached the metaphase I to metaphase II stages (MI to MII) than the percentage of control follicles observed at 0 h (0.9%, 3/318). Continued culture resulted in a further increase (P < 0.05) in the percentage of oocytes reaching MI to MII by 48 h (11.5%, 47/407), which remained unchanged at 72 h (9.9%, 40/404). The percentage of oocytes from EAN follicles reaching MI to MII did not significantly increase after 24 h of culture. However, there was an increase (P < 0.05) by 48 h of culture (8.7%, 11/126), which remained unchanged at 72 h (7.5%, 8/106). These results show that dog oocytes cultured within advanced preantral and early antral follicles in vitro are competent to resume meiosis to the metaphase stage.

Isolation and characterization of canine advanced preantral and early antral follicles

This study was designed to develop preantral follicle isolation and classification protocols for the domestic dog as a model for endangered canids. Ovary donors were grouped by age, size, breed purity, ovary weight and ovary status. Ovaries were randomly assigned to 1 of 3 digestion protocols: A) digestion and follicle isolation on the day of spaying; B) storage at 4 degrees C for 18 to 24 h prior to digestion and follicle isolation; C) digestion on the day of spaying, then incubation at 4 degrees C for 18 h prior to follicle isolation. Minced tissue was placed in a collagenase/DNase solution at 37 degrees C for 1 h. Follicles were classified by oocyte size and opaqueness and by size and appearance of the granulosa cell layers. Preantral follicles contained small, pale oocytes. Preantral follicles containing grown oocytes with dense cytoplasmic lipid were designated as advanced preantral. Only advanced preantral and early antral follicles were examined and classified further. Group 1 follicles had incomplete or absent granulosa layers, Group 2 follicles had several intact granulosa layers, while Group 3 were vesicular (early antral) follicles. Misshapen or pale grown oocytes were classified as degenerated. The percentage of intact germinal vesicles (GV) was recorded for each Group. Digestion Protocol B produced the lowest percentage of degenerated follicles (P < 0.01). Prepubertal donors had fewer (P < 0.01) follicles in each Group and more (P < 0.001) degenerated follicles than older bitches. Larger ovaries yielded the highest total number of follicles (P < 0.05). Ovary status did not affect follicle yield. Oocytes from Group 1 follicles had fewer intact GVs than those from Group 2 or Group 3 (P < 0.0001). These findings provide an opportunity for quantitative studies of the factors regulating folliculogenesis in the domestic dog as a model for endangered canids.

Analysis of sperm motility using optical tweezers

This study examines the use of optical trapping as a quantitative measure of sperm motility. The effects of laser trap duration and laser trapping power on sperm motility are described between sperm swimming force, swimmimg speed, and speed of progression (SOP) score. Sperm (SOP scores of 2-4) were trapped by a continuous-wave 1064 nm single-point gradient laser trap. Trap duration effects were quantified for 15, 10, and 5 seconds at 420 mW laser power. Laser power effects were quantified at powers of 420 mW, 350 mW, 300 mW, and 250 mW for five seconds. Swimming force, swimming speed, and SOP score relationships were examined at a trap duration and trapping power shown to minimally affect sperm motility. Swimming forces were measured by trapping sperm and subsequently decreasing laser power until the sperm escaped the trap. Swimming trajectories were calculated by custom-built software, and SOP scores were assigned by three qualified sperm scoring experts. A ubiquitous class of sperm were identified that swim with relatively high forces that are uncorrelated to swimming speed. It is concluded that sperm swimming forces measured by optical trapping provide new and valuable quantitative information to assess sperm motility.

Papanicolaou staining of exfoliated vaginal epithelial cells facilitates the prediction of ovulation in the giant panda

The giant panda is seasonally monoestrus, experiencing a single estrous with spontaneous ovulation in the spring. Therefore, accurate monitoring of the estrous cycle to pinpoint the time of ovulation is critical for the success of timed mating or artificial insemination. Analysis of exfoliated vaginal epithelial cells is a simple technique that rapidly yields information about the estrous status of a panda. Vaginal swabs were obtained during five estrous cycles of two nulliparous females. Cells were stained with the trichrome Papanicolaou and classified as basophils, intermediates or superficials. The color of stained cells, basophilic, acidophilic or keratinized, was recorded as a characteristic independent of the three standard cell types. The day urinary conjugates of estrogen fell from peak levels was considered the day of ovulation. A chromic shift occurred 8-9 days before ovulation when the majority of exfoliated vaginal cells changed from basophilic (blue) to acidophilic (pink) without accompanying nuclear or cytoplasmic changes. A second chromic shift was consistently observed 2 days prior to ovulation when keratinized (orange) cells replaced acidophils as the majority of vaginal cells. Monochrome staining of vaginal cells is sufficient to quantify superficial cells, which is a useful adjunct to behavioral and endocrinological data in determining estrous in the giant panda. However, the timing and duration of superficial cell elevations are substantially different between and within individual females, which limits the accuracy of timing ovulation for artificial insemination. The predictive value of vaginal cytology was greatly enhanced with the trichrome stain and evaluation of cell color.

The importance and potential of artificial insemination in CANDES (companion animals, non-domestic, endangered species).

Artificial insemination (AI) is the least invasive assisted reproductive technology, and is therefore of great interest to breeders of companion animals, non-domestic, and endangered species (CANDES). This most fundamental artificial breeding technique circumvents physical or behavioral impediments to natural mating and provides the means for genetic exchange between populations without transfer of live animals. In addition, because oocytes grow, mature and are fertilized in vivo and embryos are not subjected to in vitro culture conditions, AI eliminates the epigenetic effects on the female gamete that are inherent in more invasive assisted reproductive technologies. Although the management of CANDES differs significantly from current livestock husbandry practices, the cattle industry is a powerful example of the potential for AI to enhance the genetic health and sustainability of animal populations. Ultimately, successful AI requires sperm of adequate quality and quantity, oocytes that have attained nuclear maturation and cytoplasmic competence, operational gamete transport systems, accurate timing, and proper placement of sperm in the female reproductive tract. Increased understanding of semen collection, evaluation and preservation techniques, estrus synchronization and superovulation, estrus and ovulation detection, and insemination instrumentation is needed for each CANDES before AI success rates will approach those of the livestock industry. Concentrated, collaborative research in these areas must be encouraged among private breeders, universities and zoological institutions to realize the full potential of AI in the management of CANDES.

Use of laser tweezers to analyze sperm motility and mitochondrial membrane potential

We combine laser tweezers with custom computer tracking software and robotics to analyze the motility [swimming speed, VCL (curvilinear velocity), and swimming force in terms of escape laser power (Pesc)] and energetics [mitochondrial membrane potential (MP)] of individual sperm. Domestic dog sperm are labeled with a cationic fluorescent probe, DiOC2(3), that reports the MP across the inner membrane of the mitochondria located in the sperms midpiece. Individual sperm are tracked to calculate VCL. Pesc is measured by reducing the laser power after the sperm is trapped using laser tweezers until the sperm is capable of escaping the trap. The MP is measured every second over a 5-s interval during the tracking phase (sperm is swimming freely) and continuously during the trapping phase. The effect of the fluorescent probe on sperm motility is addressed. The sensitivity of the probe is measured by assessing the effects of a mitochondrial uncoupling agent (CCCP) on MP of free swimming sperm. The effects of prolonged exposed to the laser tweezers on VCL and MP are analyzed. The systems capabilities are demonstrated by measuring VCL, Pesc, and MP simultaneously for individual sperm. This combination of imaging tools is useful to quantitatively assess sperm quality and viability.

Giant Pandas: Role and efficiency of artificial insemination and genome resource banking

INTRODUCTION Historically, the breeding of giant pandas in ex situ programmes has been difficult due to behavioural incompatibility and interanimal aggression. Because some individuals fail to mate naturally, the potential loss of valuable genes is a major concern to effective genetic management (see Chapter 21). Consistently successful artificial insemination (AI) would allow incorporating genetically valuable males with behavioural or physical anomalies into the gene pool. This strategy becomes even more powerful when used in the context of a genome resource bank (GRB), an organised repository of cryopreserved biomaterials (tissue, blood, DNA and sperm) (see Chapter 7). The use of sperm cryopreservation and AI allows the movement of genes among zoos and breeding centres without needing to transfer animals, which is both stressful and costly. ‘Assisted breeding’ refers to the tools and techniques associated with helping a pair of animals propagate, from AI to embryo transfer to cloning, among others (Howard, 1999; Pukazhenthi & Wildt, 2004). With the exception of AI, there is not much need for most other assisted-breeding techniques for the giant panda. As will be demonstrated here, AI is quite adequate for dealing with most cases of infertility or with helping to maintain adequate gene diversity in the captive population. In fact, the major breeding facilities, especially the China Conservation and Research Centre for the Giant Panda (hereafter referred to as the Wolong Breeding Centre) and the Chengdu Research Base of Giant Panda Breeding, routinely use AI to increase pregnancy success.