This protocol provides a convenient set of methods, which enables extremely fast, easy, non-invasive, reliable and low-cost, molecular sex determination of birds and their non-invasive, quick, safe and easily recognizable marking shortly after hatching. Only limited handling of chicks is required. This convenient toolbox of methods complies entirely with the RRR-guidelines.
Many experiments require early determination of offspring’s sex as well as early marking of newborns for individual recognition. According to animal welfare guidelines, non-invasive techniques should be preferred whenever applicable. In our group, we work on different species of song birds in the lab and in the field, and we successfully apply non-invasive methods to sex and individually mark chicks. This paper presents a comprehensive non-invasive tool-box. Sexing birds prior to the expression of secondary sexual traits requires the collection of DNA-bearing material for PCR. We established a quick and easy method to sex birds of any age (post hatching) by extracting DNA from buccal swabs. Results can be obtained within 3 hours. For individual marking chick’s down feathers are trimmed in specific patterns allowing fast identification within the hatching order. This set of methods is easily applicable in a standard equipped lab and especially suitable for working in the field as no special equipment is required for sampling and storage. Handling of chicks is minimized and marking and sexing techniques are non-invasive thereby supporting the RRR-principle of animal welfare guidelines.
Individual recognition, sexing and genotyping are fundamental prerequisites in a variety of experimental studies. Obtaining DNA bearing material and marking subjects unambiguously (even at an early age) should have minimal impact on physiology, behavior, and survival. Whenever possible, invasive procedures should be avoided according to the RRR principle1.
Non-invasive methods are not only beneficial for the animal but also might improve the obtained data as animals are less affected by the treatments.
In birds, DNA sexing can be performed on a number of non-invasively obtainable materials as droppings2, feathers3,4 or buccal swabs3,5,9. Regardless of subject´s condition and age buccal swabs are the method of choice for avian sexing, because they are easy to perform, rarely fail and handling is short.
So far, DNA from buccal swabs was either extracted with commercially available kits3,6 or time consuming standard DNA extraction protocols3,6-8. Kits are not only rather expensive, but their protocols can impose challenges for field work. Some procedural details, e.g. drying and incubation of samples, are not practical in the field. Especially in a setting where experimental protocols require sex dependent treatment from as early as a few minutes post hatching, there is urge for a quick, non-invasive, reliable and easy method to obtain results.
Across the avian taxa a considerable toolbox for marking individuals has been developed10. The wide array of available techniques accounts for the variety of research objectives, species and budgets. However, marking small nestlings has confronted researchers with additional challenges. In some species (e.g. passerines) chicks are too small to apply leg bands and require alternative methods, which do not alter parent-offspring behavior. As awareness and interest in improving animal welfare and techniques in field and laboratory studies is growing, the use of non-invasive techniques is strongly encouraged and preferred.
This protocol provides a non-invasive, quick, easily recognizable and persistent method to individually mark very young nestlings before applying leg bands is feasible. This marking method is introduced on one of the most important avian laboratory model species, the Zebra Finch (Taeniopygia guttata)11-13. The protocol complies with all of the previously published objectives for individual marking techniques10 and has been already successfully applied14,15.
All procedures were performed in compliance with the German law for animal protection (TierSchG).
1. Preparation of Reagents and Consumables
2. Sample Collection
Wearing gloves is not essential for avian sex determination as the PCR primers cannot anneal to human DNA. For other genotyping purposes it might be advisable.
If you also intend/need to mark the chicks, do so now as described in section 6.
3. Storage of Samples Before DNA Extraction
4. DNA Extraction
5. Molecular Sex Determination
6. Marking Nestlings
For zebra finches: Apply leg bands at ten days post hatching when down feathers become hard to detect and nestling size allows ringing.
Buccal swabs can be used to obtain DNA for sex determination in a variety of small birds
Samples were collected from Zebra Finches (Taeniopygia guttata, 99 individuals, age 0 days – 5 years), Canaries (Serinus canaria), Bengalese Finches (Lonchura striata), Nightingales (Luscinia megarhynchos), Great Tits (Parus major) and Blackbirds (Turdus merula) (for all other species: sample size 1-3, age unknown) (Figure 1).
For samples taken from Zebra Finches, the success rate for the PCRs was 100%. The PCR result always matched the sex determined by prior (in adults) or later (in nestlings) phenotypic inspection. The intensity of bands did not differ systematically between nestlings or adults indicating that similar amounts of DNA-bearing material are gained from all ages.
Figure 1. Molecular sexing. Examples of sexing results from buccal swabs obtained from various avian species. 2% agarose gel stained with ethidium bromide. From left to right: size marker, Zebra Finch male, Bengalese Finch female, Blackbird male, Great Tit male, Nightingale male, Canary male, water control, size marker.
It is important to prevent Chelex carryover contamination in the PCRs
To demonstrate the effect of Chelex resin contamination in a PCR reaction, we included a small amount of Chelex beads in a PCR reaction (Figure 2). As can be seen in Figure 2A, carryover contamination of Chelex beads prevents the amplification of DNA which is further illustrated by the lack of primer dimer formation in the contaminated sample (Figure 2B). In Figure 2A lane 2 we used the same sample for the PCR without carrying over Chelex. Usually contaminated samples are easily recognizable by dark spots in the pockets of the agarose gel (Figure 2B).
Figure 2. Chelex contamination. A) Chelex carryover into the PCR reaction inhibits the amplification of DNA. From left to right: size marker, Zebra Finch male, Zebra Finch female, same sample with intentional carryover of Chelex, water control, size marker. B) Chelex beads are readily visible as dark staining in the pocket of the gel (left without Chelex, right with Chelex. The severe inhibition of the PCR reaction in the presence of Chelex is also illustrated by the missing primer dimer formation in the contaminated sample.
Samples can be stored at room temperature before DNA extraction for more than three years
In order to investigate whether successful extraction can still be performed after long storage, samples were taken repeatedly from the same bird and stored in the lab at ambient temperatures for maximally three years. The samples were stored close to a window with natural exposure to light and heat from the sun. After three years DNA was extracted and the sexing PCR performed. The result matched the one performed three years earlier (right after sampling) and did not indicate any effect of storage (Figure 3).
Figure 3. Chelex allows long-term storage of samples before and after DNA-extraction. Samples of two animals (male left, female right) were stored under different conditions as indicated in the table. Signals were obtained successfully from all samples.
Figure 4. Marking of chicks. A) Schematic representation and nomenclature of the four distinct areas of down feather growth in zebra finch nestlings: A = head, B = back, C = wings (both), D = flanks (both). B) Example pictures of nestlings which either received one of the respective ‘haircuts’ (A-D) or no ‘haircut’ (E).
Extracted DNA can be stored for more than three years at 4 °C
Zebra finch samples from the first experiment were stored for three years in a standard laboratory fridge at 4 °C and successfully retested. All samples yielded the same PCR results as directly after DNA extraction (Figure 3).
Hatchlings can be marked by trimming their down feathers to enable individual recognition from hatching on
Marking individual nestlings right after hatching by cutting their down feathers made them easily recognizable (Figures 4, 5, 6). Down feathers have a fluffy appearance as their barbs are not joined together to form a smooth vane. They can still be recognized at posthatch day 10 on the tips of the developing feathers, which by then cover the body (Figure 5). Their absence at distinct locations makes recognition easy, sometimes even without handling the nestlings (Figure 6). Applying these so called `haircuts’ is an elegant technique, which successfully fills the gap for the time from hatching until the body size of nestling zebra finches makes the application of leg bands feasible.
Figure 5. Marked Zebra Finch nestlings at post hatch day 10. Pictures show nestlings either with (scissors) or without (arrow) markings. An arrow points to the location of interest according to the respective nomenclature of down feather ‘haircuts’: A = head, B = back, C = wings, D = flanks.
Figure 6. Recognition of marked nestlings (mean age = 10 days) within the natal nest according to the nomenclature. A = head, easy to spot due to his prominent down feathers, which are only missing on the head. B = back, down feathers visible at all locations but on the back. C = wings, needs an attentive observer as both wings are missing down feathers, but nestling´s posture makes the down feathers from the head cover the right wing. D = flanks, can only be recognized by the process of elimination as its flanks cannot be seen. It can be reliably recognized as D as it shows clear down feather growth at the head, the back and its wings. E = a combination of ‘haircuts’ head (A) and back (B), is easy to distinguish as down feathers on the head and back are missing. F = a combination of ‘haircuts’ A (head) and D (flanks), which can only be differentiated through eliminating other options as its head marking is obvious and no other unidentified nestling exhibits a head marking. G = did not receive any markings and is a lot smaller than its siblings as it was the last to hatch. Additionally G is a good example for a nestling which does not express down feathers at all locations.
Sexing from buccal swabs using Chelex showed an extremely high success rate. Cutting hatchling’s down feathers enabled differentiation between nestlings until leg banding was possible.
Chelex-DNA extraction from buccal swabs yielded enough DNA to successfully perform molecular sexing. Sex determination was 100% correct as validated by sexually dimorphic plumage. The success rate reported here is markedly higher than the rate reported by two previous studies7,9. The DNA extraction with Chelex minimizes pipetting and precipitation steps in which material can be lost. However, one of the studies validating our protocol in a different species (Apus apus) still achieved a lower success rates of 89%9 even though this was already markedly higher than the 82% reported in Arima et al.7.
What could be the cause? The most crucial part is to attentively follow the protocol, including the part for how to take samples (gently swipe tissue several times in the mouth) and to prevent carry-over of Chelex beads into the PCR reaction. As Chelex is a cation exchanger it severely inhibits the PCR reaction preventing amplification in contaminated samples. Contaminated samples can be easily recognized by beads visible in the pockets of agarose gels and the lack of primer dimers.
Less likely reasons for failure to successfully sex samples could also be due to species differences or the use of a different technology to detect the band difference in the female samples.
Cutting the down feathers of hatchling zebra finches is a safe way to individually mark subjects. These ‘haircuts’ were easy to recognize until nestlings were old enough to receive numbered leg bands (e.g. at day 10 in zebra finches). This marking technique may be readily adjusted to meet different experimental demands; e.g. for video recordings markings can be limited to the head of chicks. Combinations of cuts at two positions can be applied if nests are larger than five nestlings. Keeping a predefined sequence in applying ‘haircuts’ (e.g. the first hatchling in a nest always receives ‘haircut A’, the second always receives ‘haircut B’ etc.) allows fast recognition within the hatching order throughout the nestling phase. This enables quick identification, which can reduce or even prevent handling of chicks. In zebra finches, lack of downs at one of the four locations can occur due to natural fluctuations. Thus, it may not always be possible to stick to a predefined marking sequence.
Even for someone inexperienced in handling nestlings it is a quickly to learn, safe and easy marking technique to cut the down feathers. However, as the innate gaping response of nestlings includes head movements, some people find it more difficult to place markings on the head. Error prone identification relies on precise markings. It is of eminent importance to thoroughly cut the entire down feathers at a given spot, as imperfect markings/ single left-out down feathers may later confuse identity.
This set of methods enables extremely fast, easy, non-invasive, reliable and low-cost, sex determination of birds and their non-invasive, quick, safe and easily recognizable marking within minutes after hatching.
The authors have nothing to disclose.
Many thanks to Silke Kipper, Sarah Kiefer, Michael Weiß, Conny Bartsch and Silke Voigt-Heucke for enthusiastic sample collection in the field, to Janett Birkenfeld for continued assistance, to Ulla Kobalz for the beautiful gels and to Tobias Krause for moral support.
Whatman 3MM Chromatography paper | e.g. Fisher Scientific | No.:3030-153 | |
Chelex 100 Resin | Biorad | #143-2832 | |
Taq polymerase | addgene | http://www.addgene.org/25712/ | |
leg band (Flexi number rings for birds, diameter 2,5 mm) | Horst Stengel & Sohn |