Cryopreservation produces limited long-term effects on the nematode Caenorhabditis elegans.

Cryopreservation, the freezing and later warming of biological samples with minimal loss of viability, is important in many scientific disciplines. For some applications, particularly those where there is limited available material, it is critical to ensure the maximal survival rates of cryopreserved materials. Most of the challenges encountered with such techniques take place after the warming process where cryodamage affects cell viability and future development. Here we have used the nematode Caenorhabditis elegans to investigate the effects of cryodamage caused by slow-freezing. We find that freezing results in the death of some worms, with an approximately 40% reduction in the number of worms that develop in the frozen populations, but that the effects on worms that survive are limited. For example, there are no differences in the lifetime fecundity or in lifespan between frozen and control worms, although early fecundity and body size was reduced in frozen worms. Similarly, analyses of body wall muscle structure and of pharyngeal function indicates that muscle development and function are not significantly affected by freezing. We do however determine that freezing increases the rates of matricidal hatching, where progeny hatch within the mother. Overall, these results indicate that, for worms that survive, cryopreservation produces limited long-term effects, but do indicate that some phenotypes could be used in further analyses of the cellular damage induced by cryopreservation.

Canine recommended breed weight ranges are not a good predictor of an ideal body condition score.

Breed-specific ideal bodyweight range information is widely used by dog owners and breeders as a guideline to ensure animals are within a healthy weight range. Body Condition Scoring, a method used by veterinarians to assess an animal's overall shape with regard to weight is considered to be an excellent method to determine an animal's overall body condition; these values, however, do not always correspond to published weight ranges. Here, the weight, neuter status, age and a nine-point Body Condition Score of a population of 140 purebred dogs were recorded and subsequently analysed to determine whether bodyweight was an effective predictor for Body Condition Scores. This comparison indicated that published recommended, breed-specific body weight ranges are not a good predictor for an ideal BCS and as such, guidelines for owners and breeders need to be systematically reviewed.

Time-lapse embryo imaging and morphokinetic profiling: Towards a general characterisation of embryogenesis.

In vitro fertilisation is an effective method of assisted reproductive technology in both humans and certain non-human animal species. In most species, specifically, in humans and livestock, high in vitro fertilisation success rates are achieved via the transfer of embryos with the highest implantation and subsequent developmental potential. In order to reduce the risk of multiple gestation, which could be a result of the transfer of several embryos per cycle, restrictive transfer policies and methods to improve single embryo selection have been implemented. A non-invasive alternative to standard microscopic observation of post-fertilisation embryo morphology and development is time-lapse technology; this enables continuous, uninterrupted observation of embryo development from fertilisation to transfer. Today, there are several time-lapse devices that are commercially available for clinical use, and methods in which time-lapse could be used to improve embryology are continually being assessed. Here we review the use of time-lapse technology in the characterisation of embryogenesis and its role in embryo selection. Furthermore, the prospect of using this technology to identify aneuploidy in human embryos, as well as the use of time-lapse to improve embryological procedures in agriculturally important species such as the pig and cow are discussed.

Cryopreservation of animal oocytes and embryos: Current progress and future prospects.

Cryopreservation describes techniques that permit freezing and subsequent warming of biological samples without loss of viability. The application of cryopreservation in assisted reproductive technology encompasses the freezing of gametes, embryos, and primordial germ cells. Whilst some protocols still rely on slow-freezing techniques, most now use vitrification, or ultra-rapid freezing, for both oocytes and embryos due to an associated decreased risk of damage caused by the lack of ice crystal formation, unlike in slow-freezing techniques. Vitrification has demonstrated its use in many applications, not only following IVF procedures in human embryology clinics but also following in vitro production of embryos in agriculturally important, or endangered animal species, before embryo transfer. Here, we review the various cryopreservation and vitrification technologies that are used in both humans and other animals and discuss the most recent innovations in vitrification with a particular emphasis on their applicability to animal embryology.

The effects of hyperbaric oxygen on the crystallins of cultured rabbit lenses: a possible catalytic role for copper.

Oxidative effects on lens proteins have been linked with the formation of human age-related cataract, particularly nuclear cataract. This study investigated the effects of hyperbaric oxygen (HBO)-induced oxidative stress on nuclear and cortical alpha-, beta- and gamma-crystallins of cultured rabbit lenses, using high performance liquid chromatography (HPLC). The lenses were treated with 50 atm of either 100% N(2)(control) or 100% O(2)(experimental) for 3, 6, 16 and 48 hr. The levels of reduced glutathione (GSH) and water-soluble (WS) protein decreased more rapidly in the nucleus of the O(2)-treated lens than in the cortex. The first significant loss of WS protein in each of the two regions occurred when levels of GSH had decreased by at least 90% in either the nucleus (at 6 hr) or the cortex (at 16 hr). HPLC analysis of the nuclear WS proteins indicated that beta-crystallins were the first proteins affected by the oxidative stress. Soon after HBO-treatment was initiated (at 6 hr) and prior to insolubilization of protein, nuclear beta- and gamma-crystallins moved to the higher molecular weight alpha-crystallin fraction; 2-D gel electrophoresis and Western blotting indicated the presence of disulfide-crosslinked and non-crosslinked beta- and gamma-crystallins in this fraction. Significantly different HBO-induced effects were observed on lens cortical crystallins compared to those for the nucleus. For example, gamma-crystallins in the cortex shifted very soon after HBO-treatment (at 3 hr) to slightly higher molecular weights, possibly the result of protein/glutathione mixed disulfide formation; however, this phenomenon was not observed in the nucleus. Cortical beta- and gamma-crystallins remained in solution longer than nuclear proteins following HBO-treatment of the lenses, presumably the result of protection from the four-fold higher level of GSH (22 vs 6 m M) present in the lens periphery. Surprisingly, there was no movement of beta- and gamma-crystallins to alpha(H)- and alpha-crystallin fractions in the cortex of the O(2)-treated lens, in contrast to that observed for the nucleus. Cortical crystallins appeared to go directly from being soluble to being insoluble with no high molecular weight intermediate stage. The data suggested a possible chaperone-like function for alpha-crystallin in the nucleus of the stressed lenses, but not in the cortex. HBO-induced effects on lens nuclear supernatants, which mimicked those observed for intact lenses, could be nearly completely prevented by the copper-chelator bathocuproine, but not by the iron-chelator deferoxamine. Overall, the results provide additional evidence demonstrating an increased susceptibility of the lens nucleus to oxidative stress; the greater protective ability of the cortex may be linked to a higher capacity for beta- and gamma-crystallin/glutathione mixed disulfide formation, inhibiting disulfide-crosslinked insolubilization. The data also implicate copper as a catalyst for the autoxidation of -SH groups in the lens, and suggest that alpha-crystallin chaperone-like activity may play a greater role in the lens nucleus than in the cortex in preventing oxidative insolubilization of crystallins.