Precision of age estimations from scales, otoliths, vertebrae, opercular bones and cleithra of two loaches, Misgurnus anguillicaudatus and Paramisgurnus dabryanus.
Key words: two freshwater fishes, age essessment, different structures
Misgurnus anguillicaudatus and Paramisgurnus dabryanus respectively belonging to Misgurnus and Paramisgurnus, Cobitidae, Cypriniformes, are widely distribute in Asia (You et al. 2009, Zhang et al. 2014). Due to high protein content, low fat, delicious taste and traditional Chinese medicine value, these two loaches known as "water ginseng" are very popular in the aquatic products markets of some East Asia countries like China, South Korea and Japan (Kiros et al. 2011, Gao et al. 2012, Zhang et al. 2014). Recently, because of market demands and huge decreases of their wild resources, prices of these two loaches are getting higher and higher, causing these two loaches become two most important freshwater commercial fishes in China (Fisheries Bureau of the Ministry of Agriculture of China 2014).
Researches aboutM anguillicaudatus and P. dabryanus mostly focused on the breeding physiology (You et al. 2008), nutrition (Gao et al. 2014), development (Liang et al. 1988), and toxicology (Li et al. 2003). Age estimations of these two loaches were poorly understood. There are many different structures for fish age estimation, such as scales, otoliths, vertebrae and opercular bones (Khan et al. 2013, Ilies et al. 2014, Lozano et al. 2014). To date, only the scale was used to estimate ages of these two loaches (Wang et al. 2001, 2009, Huang et al. 2015), unconcerned with other age estimation structures. The objective of this study was to compare the feasibilities and precisions of age estimations of these two loaches using five different structures which were scale, otolith, vertebra, opercular bone and cleithrum. Results obtained here can enrich basic biological data of these two loaches.
Material and Methods
M. anguillicaudatus (291 individuals) and P. dabryanus (355 individuals) were collected from Zhengzhou city, Henan Province, China, using cages. Followed by body length measurements, the scales and otoliths were taken out from 200 M. anguillicaudatus and 200 P. dabryanus selected randomly. Meanwhile, the vertebrae, opercular bones and cleithra were removed from 50 M. anguillicaudatus and 50 P. dabryanus.
Making specimens of age estimation structures
About 10 to 20 scales of each fish were sampled from the region between the third line near dorsal-fin base and lateral line. Scales were soaked and digested in distilled water for 24 hours at room temperature (20-25 [degrees]C), then washed, dried and mounted between two glass slides. The mounted scales were labelled. Before photographing, the mounted scales were immersed in anhydrous ethanol and then the slides surfaces were dried. Scales observation and photographing were performed in liquid phases (Huang et al. 2014). Observations for annual rings on scales were conducted by using stereo microscope (Leica MZ75, Germany) and photographs of scales were taken and saved (Leica DFC300 FX).
Fish heads were dissected and immersed in a 95% solution of alcohol. Otoliths were extracted using fine tweezers, rinsed in water, fixed with nail enamel and air-dried. After drying at room temperature, the otoliths were hand sanded using sandpaper with increasingly fine grit of 1000#, 1500# and 2000# and polished smooth. Otoliths were then mounted with nail enamel to prevent oxidation.
The vertebrae, opercular bones and cleithra obtained from fish specimens were dipped in a 1% sodium hydroxide of boiling water for several minutes to remove connective tissues and the attached muscles, and then immersed in 10% hydrogen peroxide for 24 hours and air-dried to prepare for microscopic observation.
Observations of annual rings on scales and otoliths were conducted by using stereo microscope (Leica MZ75, Germany) and photographs of scales and otoliths were taken and saved (Leica DFC300 FX). The other three age estimation structures (namely vertebrae, opercular bones and cleithra) were immersed in dimethylbenzene to become transparent, and then photographed and saved.
Each scale was examined three times by two people without reference to the growth information of fish. When ages estimated through the same scale specimen appeared in three different values the result was excluded. The observed age estimated through each scale, or the observed age for each fish, was determined by the modal age. The method of age estimation based on otoliths was as same as that based on scales. Annual rings were not observed on the vertebrae, opercular bones and cleithra of these two loaches. Different age estimation structures (namely scales and otoliths) from the same fish should be observed at least after half a month hiatus.
Data were analyzed by using SPSS 16.0. Photoshop software was used to process photos. The long diameter of scale was defined as the longest diameter through the scale focus, while the short diameter of scale was defined as the widest diameter perpendicular to the long diameter. The long and short diameter of 50 scales of M. anguillicaudatus and 50 scales of P. dabryanus were respectively measured to analyze their scale diameter radios. The mean coefficient of variation was used to compare the similarity of age estimations based on different structures (Chang 1982). Age bias plots (Campana 2001) were used to visually detect systematic bias between structures.
Body length frequency distributions
The body length of M. anguillicaudatus ranged from 9.04 to 15.99 cm (Fig. 1a). The average body length of M. anguillicaudatus was 12.02 cm (n = 200). The average body length of male M. anguillicaudatus was 11.96 cm (n = 89), while the average body length of female M. anguillicaudatus was 12.06 cm (n = 111). The body length of P. dabryanus ranged from 9.20 to 15.75 cm (Fig. 1b). The average body length of P. dabryanus was 12.14 cm (n = 200). The average body length of male P. dabryanus was 11.50 cm (n = 95), while the average body length of female P. dabryanus was 12.71 cm (n = 105). Body length distributions of M. anguillicaudatus and P. dabryanus (Fig. 1) met normal distributions.
Characteristics of annual rings on different structures
Annual rings on the scale and otolith of M. anguillicaudatus and P. dabryanus were distinct, while unclear or no annual rings were observed on the vertebra, opercular bone and cleithrum of these two loaches (Fig. 2).
Morphologies and characteristics of scale specimens of M. anguillicaudatus and P. dabryanus were similar. Each scale could be divided into four parts which were the top area, a base region and two lateral regions, with a smooth margin and the scale focus base. Scales of M. anguillicaudatus were near round with dense annuli (Fig. 2a), while scales of P. dabryanus were oval with sparse annuli (Fig. 2b). Ratios of the long diameter to short diameter in M. anguillicaudatus and P. dabryanus were respectively 1.03 [+ or -] 0.09:1 and 1.37 [+ or -] 0.13:1. The average diameter of scales of P. dabryanus tended to be longer than M. anguillicaudatus when these two loaches had same body length. Scale grooves of these two loaches consisted of circular grooves surrounded the scale focus and vertical grooves perpendicular to circular grooves. Vertical grooves were divided into primary and secondary radii on the basis of the original source. The former came from the focus of the scale, while the latter was initiated by somewhere away from the focus. The location of secondary radii with dense circular grooves turned dark under an incident light. As a result, annual rings of these two loaches could be distinguished through the location of secondary radii and the density of circular grooves.
Both M. anguillicaudatus and P. dabryanus, had three pairs of otoliths: lapillus otoliths, asteriscus otoliths and sagittal otoliths. Since the sagittal otoliths were fragile, we did not obtain them successfully. Asteriscus otoliths were flaky, so only the lapillus otolith with a clear pattern of alternating zones could be used for age estimation. Lapilli with no significant differences between these two loaches were defined as dorsal and ventral section or anterior and posterior section according to the direction of fish body. The dorsal side with slightly inward depression was smooth, while the ventral side formed by small particulate crystals was very protruding (Fig. 3). The location of annual rings was near to the depression of dorsal side. Annual rings could be distinct by sanding the bumps of the ventral side (Fig. 2c). There was a darker central core in the central section of lapillus otolith. Annual rings were dark, while growth bands were bright under a transmission light. Ages were read counting the number of dark zones. Annual rings on otoliths were often clear enough to provide reliable age estimations, but the sampling and processing of otoliths specimens were harder and more complicated than in other age estimation structures.
No significant differences were found in the number and morphology of vertebrae between these two loaches. Vertebrae presented a double concave, with a first concave part shallower towards the head and a second concave part deeper towards the tail. Wide translucent bands and narrow opaque bands with dense black spots were showed in M. anguillicaudatus when a second concave part towards the tail was observed using a stereoscopic microscope. Narrow opaque bands acted as annual rings. Only 46% vertebrae presented annual rings in M. anguillicaudatus. There were no obvious wide translucent bands and narrow opaque bands found in vertebrae of P. dabryanus (Fig. 2d). Therefore, vertebrae were not suitable for age estimations of these two loaches.
Opercular bone and cleithrum specimens
Opercular bones and cleithra from these two loaches had similar morphological characteristics. Opercular bones presented irregular triangular (Fig. 2e), and the latter part of cleithra presented semiterete (Fig. 2f). There were no annual rings observed on opercular bones and cleithra in these two loaches. So, opercular bones and cleithra could not serve as the structures of age estimations of these two loaches.
Comparisons of age estimations between scales and otoliths
Percent agreements of age estimated by scales and otoliths for M. anguillicaudatus and P. dabryanus were 81.5% and 79.5%, respectively. Age bias plot of ages estimated from scales compared to ages estimated from otoliths for M. anguillicaudatus revealed a smaller discrepancy (Fig. 4). The mean value of coefficients of variation (CV) between age readings of scales and age readings of otoliths for M. anguillicaudatus was 6.77%. Age estimated bias of scales and otoliths for M. anguillicaudatus showed more variations in age group 1 and age group 5. For P. dabryanus, age bias plot of ages estimated from scales compared to ages estimated from otoliths revealed a larger discrepancy (Fig. 4). The CV value between age readings of scales and age readings of otoliths for P. dabryanus was 8.09%. Age estimated bias of scales and otoliths for P. dabryanus showed more variations in age group 1 and age group 5. Least age variations between age readings of scales and age readings of otoliths for M. anguillicaudatus and P. dabryanus were observed in age group 3. Age estimates of scales were higher than those of otoliths for loach ages under or equal to three years. Age estimates of scales were lower than those of otoliths for loach ages above to three years.
Age compositions of M. anguillicaudatus and P. dabryanus were obtained by analyzing the scales and otoliths specimens, as shown in Table 1.
Fish age estimation is one of the important contents of fisheries resources research (Younger et al. 1975, Casselman 1983, David et al. 2013). Age data is the basic for analyses of fish growth, sexual maturity, and changes in population structures (Gallagher & Nolan 1999). Therefore, obtaining reliable and accurate age data by age estimation is crucial for growth analysis, population dynamics and proper management. Comparison of age estimations from different bony structures has been studied in a number of fishes to identify the most suitable structure (Khan & Khan 2009).
In addition to the scale which was easily sampled and processed, the researchers attached more and more attention to using other anatomical structures in age estimations, like otoliths (Deng et al. 2010), opercular bones (Hua et al. 2005, Li et al. 2009, Wang et al. 2011), vertebrae (Hua et al. 2005, Cai et al. 2011), cleithra (Li et al. 2009), fin rays (Xiong et al. 2006), and so on. Historically, the major part of previously published studies of age estimations for M. anguillicaudatus and P. dabryanus were made with scales, which had great limitations. By comparative analyses of five age estimation structures (scales, otoliths, vertebrae, opercular bones and cleithra), this study concluded scales of loaches (small fish) had a strong applicability for age estimation in loaches, which were easily sampled and observed. More accurate age estimations were obtained when otoliths were used. Vertebrae generally served as auxiliary age estimation structure. However, it appeared to be unreliable for these two loaches' age estimations, since annual rings on vertebrae of M. anguillicaudatus were obscure and those of P. dabryanus were not presented. Annual rings on opercular bones and cleithra were poorly defined, making age reading difficult. As a result, opercular bones and cleithra could not be used for age estimations of these two loaches. It could be concluded that scales and otoliths were the best age estimation structures of M. anguillicaudatus and P. dabryanus.
Age compositions of these two loaches were similar, showing approximate normal distribution. The number of age 1 was low, which may be related to the sampling methods (like cage fishing) by which small individuals were not easy to get. Meanwhile, the proportion of elder group dropped, which to a large extent was the result of long-term development and over utilization of natural resources of these two loaches.
The work involving animals was conducted in key lab of freshwater animal breeding at Huazhong Agricultural University in China. It is the personal goal of the researchers at this university to handle animals with care and use humane methods of euthanasia. The methods used in this study are listed as an approved method by the American Fisheries Society (2004). This study was financially supported by National Natural Science Foundation of China (project number: 31201719) to Xiaojuan Cao and Chinese National College Students Innovation Experiment Program (project number: 2015156). We specially thank Dr. Tea Tomljanovic for revising this paper.
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(1) College of Fisheries, Key Lab of Agricultural Animal Genetics, Breeding and Reproduction of Ministry of Education/Key Lab of Freshwater Animal Breeding, Ministry of Agriculture, Huazhong Agricultural University, Wuhan 437000, Hubei, People's Republic of China; e-mail: firstname.lastname@example.org, email@example.com, caoxiaojuan@mail. hzau.edu.cn, firstname.lastname@example.org, email@example.com
(2) Freshwater Aquaculture Collaborative Innovation Center of Hubei
Province, Hubei, People's Republic of China; e-mail:firstname.lastname@example.org
Received 5 December 2015; Accepted 23 August 2016
Table 1. Age compositions of M. anguillicaudatus and P. dabryanus. Age Number of Number of groups M. anguillicaudatus P. dabryanus male female male female 1 6 4 7 4 2 23 26 32 30 3 37 48 39 45 4 21 29 17 21 5 2 4 0 5 Total 89 111 95 105
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|Author:||Luo, Wei-Wei; Liu, Chuan-Shu; Cao, Xiao-Juan; Huang, Long-Fei; Huang, Song-Qian|
|Date:||Nov 1, 2016|
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