Sustainable animal production: exploring the benefits of sperm sexing technologies in addressing critical industry challenges.

The sex of the animals is of paramount importance in many animal production systems. This is particularly evident in the production of milk or in breeding programs focused on the production of female animals. In some cases, slaughter or euthanasia of animals of the unwanted sex becomes the only solution, highlighting ethical and economic concerns. As global demand for food continues to rise, the importance of addressing these issues becomes more evident. Reproductive technologies, such as sperm sexing techniques, may hold the key to addressing both animal welfare and the sustainability of animal production. The use of semen enriched with sperm capable of producing offspring of the desired sex can serve as a valuable tool for producers to exert greater control over production outcomes, not only helping to mitigate welfare issues related to the unnecessary premature death of unwanted offspring but also providing a possible ally in the face of stricter animal welfare guidelines. In addition, sexed semen can also contribute to financial gains and reduce greenhouse gas emissions and food waste associated with the less profitable part of the herd. This paper explores the positive impacts that sperm sexing can have on animal welfare, economy, and environment. It also discusses currently available options and strategies for more successful implementation of sexed semen. Partnerships between companies and scientists will be essential to find innovative ways to adapt current production systems and develop sperm sexing technologies that apply to most livestock industries.

The History and Prospects of Rabbit Sperm Sexing.

Sperm sex selection is a longstanding challenge in the field of animal reproduction. The cuniculture industry, in particular producers of males or females for breeding purposes, would greatly benefit from the pre-selection of the offspring's sex. This review article overviews the current and future developments in rabbit sperm sexing technologies, as well as the implications of implementing these methodologies in cuniculture. The first attempts of sperm sexing were performed in rabbits; however, a both efficient and cost-effective methodology was not yet developed for this species. Those included sperm sexing according to differences in sperm density, surface electric charge, pH susceptibility, antisera reaction, and flow cytometry. Separation by flow cytometry has proven to be efficient in rabbits, yielding fractions with approximately 81% and 86% purity for X- and Y-sperm, respectively. However, it is not cost-effective for cuniculture and decreases sperm quality. The advantages, limitations, and practical considerations of each method are presented, highlighting their applicability and efficiency. Furthermore, herein we explore the potential of immunological-based techniques that overcome some of the limitations of earlier methods, as well as recent advancements in sperm sexing technologies in other animal models, which could be applied to rabbits. Finally, the challenges associated with the development and widespread implementation of rabbit sperm sexing technologies are addressed. By understanding the advantages and limitations of existing and emerging methods, researchers can direct their efforts towards the most promising directions, ultimately contributing to a more efficient, profitable, and sustainable cuniculture.

Antibody-Conjugated Magnetic Beads for Sperm Sexing Using a Multi-Wall Carbon Nanotube Microfluidic Device.

This study proposes a microfluidic device used for X-/Y-sperm separation based on monoclonal antibody-conjugated magnetic beads, which become positively charged in the flow system. Y-sperms were selectively captured via a monoclonal antibody and transferred onto the microfluidic device and were discarded, so that X-sperms can be isolated and commercially exploited for fertilization demands of female cattle in dairy industry. Therefore, the research team used monoclonal antibody-conjugated magnetic beads to increase the force that causes the Y-sperm to be pulled out of the system, leaving only the X-sperm for further use. The experimental design was divided into the following: Model 1, the microfluid system for sorting positive magnetic beads, which yielded 100% separation; Model 2, the sorting of monoclonal antibody-conjugated magnetic beads in the fluid system, yielding 98.84% microcirculation; Model 3, the sorting of monoclonal antibody-conjugated magnetic beads with sperm in the microfluid system, yielding 80.12% microcirculation. Moreover, the fabrication microfluidic system had thin film electrodes created via UV lithography and MWCNTs electrode structure capable of erecting an electrode wall 1500 µm above the floor with a flow channel width of only 100 µm. The system was tested using a constant flow rate of 2 µL/min and X-/Y-sperm were separated using carbon nanotube electrodes at 2.5 V. The structure created with the use of vertical electrodes and monoclonal antibody-conjugated magnetic beads technique produced a higher effective rejection effect and was able to remove a large number of unwanted sperm from the system with 80.12% efficiency.

Pregnancy and calving rates improved using modified swim-up method for buffalo semen sexing.

Present study aimed to evaluate field fertility rate and calf sex ratio of Nili Ravi buffalo semen sexed through modified swim-up method (Animal Reproduction Science, 182, 2017, 69). For this purpose, five mature Nili-Ravi buffalo bulls kept at semen production unit, Qadirabad, Pakistan, were selected. Two consecutive ejaculates per week were collected with artificial vagina for 3 weeks. Qualified semen ejaculates were pooled and divided into two aliquots. The first aliquot was processed by routine procedure (control), whereas the second was processed by modified swim-up technique. After separation, semen was diluted in tris-citric acid extender and cryopreserved using standard techniques. Sexed semen was evaluated for fertility trials during peak breeding season. Artificially inseminated animals were examined for pregnancy rate through rectal palpation at least 3 months after insemination under field conditions. Calving ratio of female and male calves were recoded after Parturition. The fertility rate was higher (p < .05) in X-sorted sperm (70%) as compared with control (47%). The female calf ratio was higher (p < .05) in X-sorted sperm (78.58%) compared with control (53.3%). In Conclusion, conception rate and production of female calf were significantly higher with sexed semen separated through modified swim-up method compared with unsexed control.

An Exploration of Current and Perspective Semen Analysis and Sperm Selection for Livestock Artificial Insemination.

Artificial insemination of livestock has been a staple technology for producers worldwide for over sixty years. This reproductive technology has allowed for the rapid improvement of livestock genetics, most notably in dairy cattle and pigs. This field has experienced continuous improvements over the last six decades. Though much work has been carried out to improve the efficiency of AI, there are still many areas which continue to experience improvement, including semen analysis procedures, sperm selection techniques, sperm sexing technologies, and semen storage methods. Additionally, the use of AI continues to grow in beef cattle, horses, and small ruminants as the technology continues to become more efficient and yield higher pregnancy rates. In this review, AI trends in the various livestock species as well as cutting edge improvements in the aforementioned areas will be discussed at length. Future work will continue to refine the protocols which are used for AI and continue to increase pregnancy rates within all livestock species.

Differential proteins associated with plasma membrane in X- and/or Y-chromosome bearing spermatozoa in indicus cattle.

The differential proteins associated with plasma membrane of spermatozoa are less known, identification of which shall help overcome limitations of currently used methods of sperm sexing, considered as a high priority for livestock sector of many countries. This study has reported plasma membrane proteomics of unsorted spermatozoa and differential expression of plasma membrane-associated proteins between X- and Y-chromosome bearing spermatozoa of indicus cattle (Bos indicus). Isolation of plasma membrane fraction using percoll gradient, relatively a rapid method, from bovine spermatozoa has been reported to enrich isolation of plasma membrane proteins. Significant enrichment for plasma membrane-associated proteins was observed in plasma membrane fraction (p < .05) as compared to the total cell lysate using LC-MS/MS. Furthermore, these experiments were conducted in flow cytometry sorted, sexed-semen samples. Thirteen proteins were identified as differentially abundant between X- and Y-sorted spermatozoa. Among these, two proteins were downregulated in Y-sorted spermatozoa compared to the X-sorted spermatozoa (p < .05), while four and seven proteins could be noted in X- and Y-sorted spermatozoa, respectively. Proteins that are presumed to support sperm capacitation and sperm migration velocity were found to be abundant in Y-sorted spermatozoa while those associated with structural molecule activity were identified as abundant in X-sorted spermatozoa in the present study. Our study provides better insight into the plasma membrane proteomics of spermatozoa of indicus cattle and furnishes data that might aid in design and development of alternate and open technology for sex-sorting of semen.

Production of monoclonal antibody against recombinant bovine sex-determining region Y (SRY) and their preferential binding to Y chromosome-bearing sperm.

Separation of X and Y chromosome-bearing sperm is an appropriate method for the selection of desired sex of offspring to increase the profit in livestock industries. The purpose of this study was the production of a monoclonal antibody against recombinant bovine sex-determining region Y protein for separation Y sperm. The hybridoma cells from splenocytes of immunized female's balb/C mice and Sp2/0 cells were made. The binding affinity of our monoclonal antibody (mAbSRY2) was compared with mouse monoclonal SRY-15. The Western blot method indicated that mAbSRY2 successfully detected the rbSRY protein. The specificity and sensitivity of mAbSRY2 is comparable to SRY-15 commercially ones. The SRY gene in 100% of bull semen contains the Y chromosome that had the strongest binding affinity to mAbSRY2 was synthesized. In other words, the binding affinity of semen contains the X sperms near the negative control. In general, this immunological method can help to separate X from Y sperms. However, the mAbSRY2 is bind to Y-bearing sexed sperm, but in the future; the sexed sperms need to apply in farms.

Pre-determination of sex in pigs by application of CRISPR/Cas system for genome editing.

In livestock industries, one sex is usually preferred because of the impact on the production (e.g. milk from cows, eggs from laying hens). Furthermore, in pig production, the male-specific boar taint is a big hurdle for consumer acceptance. Consequently, a shift in the ratio towards the desired sex would be a great benefit. The most widely applied method for pre-determination of the sex is fluorescence-activated sperm sorting, which relies on the different DNA content of the X- and Y-chromosomal sperm. However, the successful practical adaption of this method depends on its ease of use. At present, sperm sexing via fluorescence-activated cell sorting (FACS) has only reached commercial application in cattle. Nevertheless, sperm sexing technology still needs to be improved with respect to efficiency and reliability, to obtain high numbers of sexed sperm and less invasive sperm treatment to avoid damage. New genome editing technologies such as Zinc finger nucleases (ZFN), Transcription-activator like endonucleases (TALENs) and the CRISPR/Cas system have emerged and offer great potential to affect determination of the sex at the genome level. The sex-determining region on the Y chromosome (SRY) serves as a main genetic switch of male gender development. It was previously shown that a knockout of the SRY gene in mice and rabbits displayed suppressed testis development in the fetal gonadal ridges resulting in a female phenotype. These new technologies hold great opportunities to pre-determine sex in pigs. However, further investigations are needed to exploit their full potential for practical application.

Review on Sperm Sorting Technologies and Sperm Properties toward New Separation Methods via the Interface of Biochemistry and Material Science.

Successful fertilization in mammals requires spermatozoa to efficiently traverse the female reproductive tract to meet the egg. This process naturally selects high quality sperm cells for fertilization, but when artificial reproductive technologies are used such as in vitro fertilization, intracytoplasmic sperm injection, or intrauterine insemination, other methods of sperm selection are required. Currently, technology enables sperm sorting based on motility, maturity as defined by zeta potential or hyaluronic acid binding site expression, absence of apoptotic factors, appropriate morphology, and even sex. This review summarizes current knowledge on all known methods of sperm cell sorting, compares their efficiency, and discusses the advantages and limitations of each technique. Scope for further refinement and improvement of current methods are discussed as is the potential to utilize a variety of materials to innovate new methods of sperm separation.

Goat Polyclonal Antibody Against the Sex Determining Region Y to Separate X- and Y-Chromosome Bearing Spermatozoa.

BACKGROUND: Sex selection of sperm by separating X- and Y-chromosome bearing spermatozoa is critical for efficiently obtaining the desired sex of animal offspring in the livestock industry. The purpose of this study was to produce a goat polyclonal antibody (pAb) against the bovine Sex Determining Region Y chromosome (bSRY) to separate female- and male-bearing spermatozoa. METHODS: To produce a goat polyclonal antibody against bSRY, a female goat was subcutaneously immunized with 27 kDa of recombinant bSRY (rbSRY) protein as the antigen. The anti-bSRY pAb was purified by ion-exchange chromatography. The purity of the pAb was determined using the SDS-PAGE method. The biological activity of the anti-bSRY pAb was examined using PCR to assess the binding affinity of pAb for the bSRY antigen and commercially sexed bull sperm. RESULTS: The total amount of purified anti-bSRY pAb was approximately 650 mg/goat serum (13 mg/mL). Interestingly, our data showed that the binding affinity of our pAb to the Y bearing was high, while the binding affinity of that to the X-chromosome bearing sperm was similar to the negative control. CONCLUSION: In conclusion, our findings show that the goat anti-SRY pAb specifically binds to Y-chromosome bearing sperm that suggesting its potential use for sex selection.

Sêmen sexado através de citometria de fluxo e centrifugação por gradiente de concentração / Semen sexed using flow cytometry and concentration gradient centrifugation / Semen sexado a través de citometría de flujo y centrifugación por gradiente de concentración

Resumo O objetivo deste trabalho foi apresentar uma revisão completa e atualizada sobre a origem do sêmen sexuado, os requisitos e as técnicas de sexagem espermáticas. Nas últimas décadas, desenvolveram-se várias tecnologias na área da reprodução animal. O sêmen sexado é uma biotecnologia recente que ainda se encontra em fase de estudo e aperfeiçoamento em diversas etapas, devido a que o processo de sexagem causa estresse ao espermatozoide, e o deixa mais sensível ao processo de armazenamento; isto interfere diretamente na fertilidade. Esta tecnologia, que chegou ao Brasil em 2004, vem ganhando adeptos entre produtores que desejam produzir animais mais homogêneos para o sacrifício ou para a produção de leite. O uso do sêmen sexado tem sido difundido em muitos rebanhos do mundo, já que se apresenta como uma técnica com um direcionamento maior na seleção do sexo. Muitas técnicas têm sido utilizadas com a finalidade de buscar uma maior separação de espermatozoides portadores de cromossomas X e Y, com mínima agressão espermática. Desta forma, a utilização da sexagem espermática tem obtido resultados na aplicação de biotecnologias da reprodução assistida, e com isso tem elevado o lucro no melhoramento genético e tem otimizado a produtividade no sexo escolhido. Entretanto, ainda existem muitas limitações, principalmente referentes al tempo de exposição, o índice de aproveitamento e os resultados de índices de gestação em condições de campo. Por outro lado, a dose de sêmen sexado pode custar de duas a oito vezes o valor de uma convencional; da mesma forma, o seu uso avança no Brasil.

Abstract This study aimed to present a complete and updated review on the origin of sexed semen, as well as on the requirements and techniques of sperm sexing. In the last decades, several technologies were developed in the field of animal reproduction. Sexed semen is a recent biotechnology that is still under study and refinement in various stages, because the sexing process causes stress to the sperm, leaving it more sensitive to the storage process; this directly interferes with fertility. This technology, which arrived in Brazil in 2004, has been gaining support among producers who want to produce more homogeneous animals for slaughter or for dairy production. The use of sexed semen has been disseminated in many herds of the world, since it is a technique with better results in the selection of sex. Many techniques have been used in order to seek a greater separation of sperms carrying X and Y chromosomes, with minimal sperm aggression. In this way, the use of sperm sexing has obtained results in the application of assisted reproductive biotechnologies, which has increased the gain in genetic improvement and has optimized productivity in the chosen sex. In the meantime, there are still many limitations, mainly concerning exposure time, exploitation rate, and the results of pregnancy rates in field conditions. On the other hand, the dose of sexed semen can cost two to eight times the value of conventional semen; nevertheless, its use progresses in Brazil.

Resumen El objetivo de este trabajo fue presentar una revisión completa y actualizada sobre el origen del semen sexado, los requisitos y las técnicas de sexaje espermáticas. En las últimas décadas, se desarrollaron varias tecnologías en el área de la reproducción animal. El semen sexado es una biotecnología reciente que aún se encuentra en fase de estudio y perfeccionamiento en diversas etapas, debido a que el proceso de sexaje causa estrés al espermatozoide, y lo deja más sensible al proceso de almacenamiento; esto interfiere directamente en la fertilidad. Esta tecnología, que llegó a Brasil en 2004, viene ganando adeptos entre productores que desean producir animales más homogéneos para el sacrificio o para la producción lechera. El uso del semen sexado ha sido difundido en muchos rebaños del mundo, ya que se presenta como una técnica con un direccionamiento mayor en la selección del sexo. Muchas técnicas han sido utilizadas con el fin de buscar una mayor separación de espermatozoides portadores de cromosomas X y Y, con mínima agresión espermática. De esta forma, la utilización del sexaje espermático ha obtenido resultados en la aplicación de biotecnologías de la reproducción asistida, y con eso ha elevado la ganancia en el mejoramiento genético y ha optimizado la productividad en el sexo escogido. Entretanto, aún existen muchas limitaciones, principalmente referentes al tiempo de exposición, la taza de aprovechamiento y los resultados de tazas de gesta ción en condiciones de campo. Por otro lado, la dosis de semen sexado puede costar de dos a ocho veces el valor de una convencional; así mismo, su uso avanza en Brasil.

An immunological approach of sperm sexing and different methods for identification of X- and Y-chromosome bearing sperm.

Separation of X- and Y-chromosome bearing sperm has been practiced for selection of desired sex of offspring to increase the profit in livestock industries. At present, fluorescence-activated cell sorter is the only successful method for separation of X- and Y-chromosome bearing sperm. This technology is based on the differences in DNA content between these two types of sperm and has been commercialized for bovine sperm. However, this technology still has problems in terms of high economic cost, sperm damage, and lower pregnancy rates compared to unsorted semen. Therefore, an inexpensive, convenient, and non-invasive approach for sperm sexing would be of benefit to agricultural sector. Within this perspective, immunological sperm sexing method is one of the attractive choices to separate X- and Y-chromosome bearing sperm. This article reviews the current knowledge about immunological approaches, viz., H-Y antigen, sex-specific antigens, and differentially expressed proteins for sperm sexing. Moreover, this review also highlighted the different methods for identification of X- and Y-sperm.

Storage of sexed boar spermatozoa: Limits and perspectives.

Despite the great potential application of sex-sorted spermatozoa in swine, the technology is not practiced in the pig industry because of technical factors and species-specific issues. The susceptibility of boar spermatozoa to stresses induced by the sorting procedure, the relative slowness of the sex-sorting process together with the high sperm numbers required for routine artificial insemination in pig are some of the main factors limiting the commercial application of this technology in pigs. This review briefly describes the damage to spermatozoa during sex sorting, focusing on an additional limiting factor: increased susceptibility of sexed boar spermatozoa to injuries induced by liquid storage and cryopreservation that, in turn, impairs sperm quality leading to unsatisfactory results in vivo. Strategies to extend the lifespan of sex-sorted boar spermatozoa and to improve their fertilizing ability after liquid storage or cryopreservation need to be implemented before this technology can be used in pig farms. In this regard, encapsulation in barium alginate membranes could be a promising technique to optimize the in vivo use of sexed boar spermatozoa, by protecting, targeting, and controlling the release of sperm into the female genital tract.

Flow cytometric sexing of spider sperm reveals an equal sperm production ratio in a female-biased species.

Producing equal amounts of male and female offspring has long been considered an evolutionarily stable strategy. Nevertheless, exceptions to this general rule (i.e. male and female biases) are documented in many taxa, making sex allocation an important domain in current evolutionary biology research. Pinpointing the underlying mechanism of sex ratio bias is challenging owing to the multitude of potential sex ratio-biasing factors. In the dwarf spider, Oedothorax gibbosus, infection with the bacterial endosymbiont Wolbachia results in a female bias. However, pedigree analysis reveals that other factors influence sex ratio variation. In this paper, we investigate whether this additional variation can be explained by the unequal production of male- and female-determining sperm cells during sperm production. Using flow cytometry, we show that males produce equal amounts of male- and female-determining sperm cells; thus bias in sperm production does not contribute to the sex ratio bias observed in this species. This demonstrates that other factors such as parental genes suppressing endosymbiont effects and cryptic female choice might play a role in sex allocation in this species.

Validação comparativa utilizando PCR quantitativo em tempo real (qPCR) e PCR convencional de sêmen bovino centrifugado em gradiente de densidade contínuo / Comparative validation using quantitative real-time PCR (qPCR) and conventional PCR of bovine semen centrifuged in continuous density gradient

The objective of the present study was to determine the sperm enrichment with X-bearing spermatozoa, after one centrifugation in a Percoll or OptiPrep continuous density gradient, using quantitative real-time polymerase chain reaction (qPCR) of sperm DNA and resultant in vitro-produced bovine embryos by PCR. Frozen/thawed sperm was layered on density gradients and the tubes were centrifuged. Supernatants were gently aspirated and the sperm recovered from the bottom of the tubes. Cleavage and blastocyst rates were determined through in vitro production of embryos and PCR was performed to identify the embryos' genetic sex. A difference in blastocyst rate was found in the Percoll treatment compared to OptiPrep (P<0.05). The percentage of female embryos in the Percoll and OptiPrep groups was 62.0 percent and 47.1 percent, respectively. These results were confirmed by qPCR of spermatozoa DNA and underestimation was seen only in the Percoll group. It was possible to sexing sperm using simple approach.

O objetivo do presente estudo foi determinar o enriquecimento de espermatozoides portadores do cromossomo X após a centrifugação em gradiente de densidade contínuo de Percoll ou OptiPrep, utilizando reação em cadeia da polimerase quantitativa em tempo real (qPCR) do DNA do espermatozoide e dos embriões bovinos produzidos in vitro resultantes pela PCR convencional. Espermatozoides descongelado foram depositados em gradientes de densidade e os tubos foram centrifugados. Os sobrenadantes foram gentilmente aspirados e os espermatozoides recuperados do fundo dos tubos. As taxas de clivagem e de blastocisto foram determinadas pela produção in vitro de embriões e a PCR foi realizada para a identificação genética do sexo dos embriões. Verificou-se diferença na taxa de blastocistos entre os grupos Percoll e OptiPrep (P<0,05). A porcentagem de embriões de fêmeas nos grupos Percoll e OptiPrep foi de 62,0 por cento e 47,1 por cento, respectivamente. Estes resultados foram confirmados pela qPCR do DNA de espermatozoides e uma subestimação foi observada no grupo do gradiente de densidade de Percoll. Foi possível a sexagem de espermatozoides utilizando uma metodologia simples.