This protocol describes a detailed methodology for detecting H2O2 localization within Solea senegalensis spermatozoa using a sensitive fluorochrome DCFH-DA for ROS, a live mitochondria stain for mitochondria, and DAPI for nuclei visualization, respectively. The protocol is designed to be performed within 2 h with either fresh or thawed spermatozoa.
Oxidative stress is one of the important factors in decreasing sperm quality. Developing efficient protocols for detecting reactive oxygen species (ROS) in spermatozoa is of high importance in any species, but these methods are rarely used and even less in teleost. Cryopreservation is a useful technique in aquaculture for different purposes, including gene banking and guaranteed sperm availability throughout the year. Freezing/thawing procedures could cause ROS production and damage the sperm cells. Considering the prospective damage that an excess of ROS production could cause in spermatozoa depending on their localization, here a detailed methodology to detect H2O2 and to evaluate its intracellular localization by confocal microscopy is provided. For this purpose, a combination of 3 fluorochromes (2′,7′-Dichlorodihydrofluorescein diacetate (DCFH-DA), a live mitochondria stain and 4′,6-Diamidino-2-phenylindole dihydrochloride (DAPI)) are used to evaluate the co-localization of H2O2 with spermatozoa nuclei or mitochondria in Solea senegalesis sperm samples.
The reactive oxygen species production has been linked with sperm quality recently1. Although ROS production in mitochondria can be considered a normal physiological process, oxidative stress by an excess of ROS production is a clear cause of damage in spermatozoa at different levels. In humans, oxidative stress is associated with male infertility, altering motility and the ability to undergo capacitation2; in mammals, change of DNA integrity in frozen sperm samples has been also related to synthesis of H2O23.
Cryopreservation is a common technique for gene banking in aquaculture. This technology is particularly important in species with reproductive problems such as Solea senegalensis. This valuable species in the market shows reproductive dysfunction in individuals born in captivity due to a lack of courtship. This fact makes sperm cryopreservation necessary to have sperm availability for artificial fertilization. However, cryopreservation could be a source of oxidative stress that could be detrimental for spermatozoa4 as studies have reported a beneficial effect of antioxidant supplementation. ROS inhibition through mitochondrial-targeted antioxidant was reportedly beneficial for sperm cryopreservation in yellow catfish5.
Therefore, the levels of ROS in sperm samples are important to know, particularly after cryopreservation6,7 because these molecules have been recognized as a drawback for sperm survival and fertility8. Moreover, studying the distribution of ROS within the cell could be crucial to infer the level of potential damage. As an example, low levels of ROS in the mitochondria could be assumed normal and compatible with sperm function, but high levels of ROS within the nucleus could be indicators of spermatozoa DNA damage. H2O2 is one of the most relevant ROS that could be released from the mitochondria and penetrate the nucleus because it is a small and charge-less molecule9. Dichlorofluorescein diacetate (DCFH-DA) can specifically reveal intracellular peroxide emitting green fluorescence. In this article, a detailed protocol for detecting H2O2 intracellular localization in Solea senegalensis sperm using confocal microscopy is presented.
NOTE: Fluorochrome incubation and confocal analysis will take at least 2-3 h for a control and a treated sample. Data processing is not included in this time calculation. Required materials can be found in the Table of Materials. This protocol can be applied to fresh or cryopreserved spermatozoa. Solea senegalensis is a fish species that spawns in cold water, work always under cold conditions (4-7 °C). See Figure 1 for a general view of the protocol.
1. Preparatory Work Before the Experiment
2. Sample Preparation Before Fluorochrome Incubation
NOTE: Gentle handling of spermatozoa is desirable when pipetting and resuspending.
3. Fluorochrome Incubation
NOTE: Fluorochromes must be handled in low light conditions, especially when in solution.
4. Sample Preparation for Confocal Microscopy
5. Confocal Setup Prior to the Experiment
NOTE: Depending on the microscope, DCFH-DA could be "burnt". Establish the best conditions with a non-valuable sample first.
6. Acquisition of Images
7. Creating a 3D Image Video
Confocal microscopy is an ideal method for intracellular ROS evaluation in teleost sperm. The combination of the three fluorochromes (DAPI, a mitochondria stain and DCFH-DA) presented in this study (Figure 1) provides many useful information that can be applied in basic research and can have applications in improving procedures used in industrial aquaculture plants, such as cryopreservation protocols. Different types of analysis may be carried out in order to correlate intracellular ROS presence and other parameters: motility, viability, different patterns between good and bad breeders, activation of motility or seasonal sperm variations among many others. In the present work, two different patterns of intracellular H2O2 distribution within the spermatozoa are shown: collocated with mitochondrion or spread in the nucleus (Figures 2, 3). Those spermatozoa showing low potential damage produced by ROS showed DCFH-DA labelling only in the mitochondria whereas those suffering DNA damage showed DCFH-DA labelling also in the nuclei. Confocal microscopy software allows to create useful videos and provide easy and fast colocalization graphs.
Figure 1. General overview of the protocol. Please click here to view a larger version of this figure.
Figure 2. Example of confocal image acquisition. A. Scheme of the sample B. DAPI channel (labelling dsDNA). C. Mitochondria stain channel (labelling mitochondrion). D. Mitochondria stain channel merged with DAPI channel. E. DCFA-DH channel (labelling intracellular H2O2). F. DCFA-DH channel merged with DAPI channel. G. Merge of the three channels. Abbreviations: n: nuclei, mt: mitochondria, f: flagellum and mb: membrane. Scale bar: 5 μm. Please click here to view a larger version of this figure.
Figure 3. Different patterns of intracellular H2O2 videodan Solea senegalensis spermatozoa (Volume render). Resulting channels of spermatozoa showing intracellular ROS in the nuclear fossa and mitochondrion (A, C, E). Resulting channels of spermatozoa showing intracellular H2O2 also within the nuclei (B, D, F). A and B: DAPI. C and D: DCFH-DA. E and F: Mitochondria stain. Please click here to view a larger version of this figure.
It is well known that mitochondria are key organelles for sperm motility and function. These organelles are concurrently directly involved in ROS production. Interestingly, controlled levels of ROS are needed for proper sperm function1. Positive relationships between fertility and oxidative stress have been shown in mammals11 but excessive levels affect sperm quality12. One crucial factor that could be decisive towards a positive or negative effect is not only ROS levels but also ROS intracellular localization. One of the deleterious effects of ROS is producing DNA damage9 and therefore the nuclear presence of ROS could be an indicator of potential damage in the nucleus whereas ROS levels could be normal in mitochondria. It is necessary to supplement existing quantitative methods (e.g., flow cytometry) with techniques like confocal microscopy that could provide information about ROS intracellular localization.
Confocal microscopy is an optimal option to visualize the intracellular localization of ROS. The use of specific fluorochromes such as a live mitochondria stain and DAPI allows the visualization of mitochondria and nucleus respectively and the combination of these molecules with DCFH-DA allows the intracellular localization of peroxide.
The critical steps within the protocol are fluorochrome incubation and confocal setup. Both steps should be optimized and carefully performed to obtain reproducible and consistent results. Methodology modifications should be performed at these two levels depending on the seminal plasma used. Therefore, fluorochrome incubation should be adapted. Temperatures and storage conditions significantly differ among sperm samples, and most of the protocols are optimized for mammals.
Here, a protocol for teleost sperm samples, particularly for Solea senegalensis spermatozoa, is described (Figure 1). Successful labeling of nuclei and mitochondria have been performed using the described protocol and ROS presence has been reveal using DCFH-DA (Figure 2). Results indicate that co-localization of H2O2 have been found in the nuclei or mitochondria depending on the sperm sample (Figure 3). As previously explained, those samples with a high percentage of spermatozoa displaying high levels of ROS within the nucleus would be prone to DNA damage. This protocol has a unique limitation, the requirement of expensive equipment (confocal microscope), but it could have future utility in selecting sperm samples with low presence of ROS within the nucleus for cryopreservation purposes.
The authors have nothing to disclose.
We thank AQUAGAMETE FA 1205 COST Action. This work was financially supported by AGL201568330-C2-1-R project (MINECO/FEDER). David G. Valcarce was funded by Junta de Castilla y León (EDU1084/2012) and Fondo Social Europeo. Authors acknowledge Dr. Ana Riaza and Stolt Sea Farm S.A., Dr. Paulino de Paz, Dr. Ignacio Martínez Montero and José Ramón Guiérrez. We also thank Paula Fernández Colado for videography.
2′,7′-Dichlorodihydrofluorescein diacetate (DCFH-DA) | Sigma-Aldrich | D6883 | |
4′,6-diamidino-2-phenylindole (DAPI) | Sigma-Aldrich | D9542 | |
CaCl2 | Sigma-Aldrich | C1016 | |
Confocal Microscopy | Zeiss | LSM800 | |
Cover slips | Thermo Fisher Scientific | 12-541B | |
DMSO, Analytical Grade | Sigma-Aldrich | W387520 | |
HEPES | Sigma-Aldrich | H3375 | |
KCl | Sigma-Aldrich | P9541 | |
Methanol, Analytical Grade | Sigma-Aldrich | 34860 | |
MitoTrackerDeep Red | Thermo Fisher Scientific | M22426 | |
Microcentrifuge (refrigerated) | Thermo Fisher Scientific | 75002441 | |
NaCl | Sigma-Aldrich | S7653 | |
Neubauerchamber | Sigma-Aldrich | BR717810 | |
Slides | Thermo Fisher Scientific | 10143562BEF |