Japanese mackerel in the high seas of the Northwest Pacific Ocean, randomly collected by fishing vessels, were studied in the sampling area of 39 - 44˚N, 147 - 154˚E, and the sampling period was from April to December (fishing season) in 2018 and 2019. Samples were taken four times a month, 100 tails were taken each time, if the number of tails was less than 100, and all samples were taken totaling 2833 tails (Frozen and shipped back to the lab via transport ship). The fishing date, latitude and longitude of each sampling location were recorded, and the samples were numbered and registered. The sampling area is shown in Figure 1.

Body length, fork length and full length of Japanese mackerel were measured by tape measure (accurate to 1 mm); body weight was measured by electronic balance (accurate to 0.1 g, Error range in ±0.1 g). The differences between fork length and body weight of Japanese mackerel by sex were examined by analysis of covariance (ANOVA), and then the fork length-weight growth relationship was fitted by power function [21] [22], as shown in Equation (1).

W i = a × L i b (1)

L_i denotes the mean fork length (mm) of the ith fork length group, W_i is the mean weight (g) corresponding to L_i, a is the condition factor for growth, and b is the power index coefficient.

During the life cycle of teleosts, the inner cavity of the skull is lined with carbonate deposits of “small stones” called otoliths. The main mineral component of otoliths is CaCO₃, and fish rely on otoliths to distinguish sounds and maintain body balance [23]. Otoliths are used to identify the age of fish because the rate of CaCO₃ deposition in otoliths varies with season, water temperature and physiological changes during the development of individual fish [24], resulting in a regular distribution of opaque zone and translucent zone around the core of otoliths, with one layer of transparent zone plus one layer of opaque zone being 1 age. In this paper, the cross-section of Japanese mackerel otoliths was used as a basis for age identification. The polished otoliths were photographed under a 100× light microscope (model: Olympus BX53), and the annual diameter and otolith diameter on the otolith photographs were measured by the measurement software Image J. The Dahl-Lee hypothesis was used to derive the fork length conversions for each age group of Japanese mackerel [25] [26]:

L i R i = L R (2)

where L_i is the back-calculated fork length (mm) of the ith age or annual whorl of Japanese mackerel; L is the fork length (mm) of that individual; R_i is the ith annual whorl diameter, which refers to the straight-line distance (mm) from the core point of the otolith to the ith annual whorl of the otolith, and the whorl pattern is measured by the outer edge of the opaque band; R is the otolith diameter, which refers to the straight-line distance (mm) from the core point of the otolith to the outermost edge. The schematic diagram of otolith chronology measurement is shown in Figure 2.

To enhance the accuracy of age identification, the otoliths used for age reading should be relatively transparent in cross-section, with the whorls clearly visible, and as much as possible, the secondary whorls should be brought together in

one place during the polishing process to reduce the interference with age identification. When measuring the diameter of the whorls on the photographs of the otoliths, the alternating zone between the transparent and opaque bands in transmitted light was used as the location of the annual whorls, and the diameter of all the secondary whorls, annual whorls and interfering whorls was recorded [26]. Each otolith age reading was performed independently of each other by two persons with solid otolith reading experience, and the age identification was considered reliable if the judgment was consistent or re-reading or discarding the sample if it was inconsistent.

In fisheries research, the von Bertalanffy growth equation can elucidate the age-dependent variation of length and weight of fish, and the growth process can be fitted with the data of minimum parameters. The equation is generally used to fit and describe the growth pattern of fish, and the least squares method is used to determine the optimal growth parameters for the von Bertalanffy growth equation [21] [27].

Fork length growth equation.

L t = L ∞ × { 1 − e [ − K × ( t − t 0 ) ] } (3)

Weight growth equation.

W t = W ∞ × { 1 − e [ − K × ( t − t 0 ) ] } (4)

L_t and W_t denote the fork length (mm) and weight value (g) of Japanese mackerel at age t; L_∞ and W_∞ denote the ultimate fork length (mm) and ultimate weight (g) of Japanese mackerel; t₀ denotes the age when the theoretical fork length (L_t) or weight (W_t) is equal to zero, often a negative number; K is the average curvature of the growth curve, indicating the relative rate of convergence to the asymptotic value.

It was found that there was no significant difference in fork length and body weight between male and female Japanese mackerel individuals (P > 0.05). The relationship between fork length and body weight was expressed as W = 2.0 × 10⁻⁶ L^3.289 (r = 0.9764,n = 2833), where the growth condition factor a was 2 × 10⁻⁶ and the power index coefficient b was 3.289 (Figure 3).

The weight growth equation is:

W t = 1046.74 × { 1 − e [ − 0.264 × ( t + 1.06 ) ] } 3.289 (5)

The weight growth rate of Japanese mackerel with age as well as weight change curve can be plotted from the weight growth equation (Figure 4). From Figure 4(a), it can be seen that during the period from 0 to 8 years of age, the body weight growth rate was the smallest at age 0, at 37.33 g/yr, but the bodyweight growth acceleration (slope of the curve d²Wt/dt²) was the largest at this time, and the Japanese mackerel grew the fastest. The body weight growth rate continued to increase from 0 to 3.1 years of age, which is the rapid growth period of Japanese mackerel, and the bodyweight growth acceleration was 0 at 3.1 years of age when the bodyweight growth rate reached the maximum value of 122 g/yr. Thereafter, the bodyweight growth rate gradually decreased from 3.1 to 8 years of age, indicating that the growth and development of Japanese mackerel entered a slow growth period.

As can be seen from Figure 4(b), the body weight growth rate also showed a trend of accelerating and then decelerating in the range of body weight change from 0 to 910 g. When the bodyweight growth acceleration was 122 g/yr, the corresponding body weight was 310 g. Then the bodyweight growth acceleration became negative and the bodyweight growth rate decreased gradually, and the Japanese mackerel body weight increased slowly. When the weight growth acceleration was 122 g/yr, the corresponding weight was 310 g. Then the weight growth acceleration became negative, the weight growth rate gradually decreased, and the weight gain of Japanese mackerel became slower. Therefore, the inflection point weight of Japanese mackerel in this study was 310 g, the inflection point age t_p = 3.1 years, and the inflection point fork length L_p = 309 mm.

The relationship between fork length and body weight of pelagic fishes has been shown to be a power function [21] [22] [23] [24] [25], and in this study, we also found a significant relationship between fork length and body weight of Japanese mackerel (R² = 0.9764, n = 2833). It is generally believed that the power index in the relationship between fork length and body weight can be used to determine whether the fish is growing at the same rate if the power index is 2.5 < 3 < 3.5, it means that the fish is growing at the same rate, which means that the growth rate of the individual in the three directions of length, width and height is close to each other in the process of growing from small to large [21].

Most pelagic fish age identification is based on otoliths, and the resin-embedded otolith molds are polished to a thickness of about 0.2 mm by a grinding and polishing machine, and the age is identified and the whorl diameter is measured under an optical microscope, based on this age identification method it is easier to determine the actual age composition of the fish [6] [25] [27], but there is sometimes some error in the accurate interpretation of the otoliths [28]. To enhance the accuracy of age determination, the otoliths used for age determination should be relatively transparent in cross-section and the whorls should be clearly visible, and as much as possible, the miscellaneous whorls should be brought together in one place during the polishing process to reduce the interference with age determination. When measuring the whorls on the otolith photographs, the alternating transparent and opaque bands in transmitted light were used as the location of the annual whorls, and the whorls of all the secondary whorls, annual whorls, and interfering whorls were recorded [29]. In this study, the average fork length values corresponding to the age back-calculation (with a margin of error of ±2 cm) were determined as the fork lengths corresponding to different ages of Japanese mackerel. All data were observed and recorded by two researchers with experience in age identification, and the age-fork length data recorded by the two researchers were compared, and the error range of ±1 cm for each age corresponding to the fork length was considered as the same data, and the data table of age-fork length relationship was finally obtained.

To verify the accuracy of otolith age identification, the growth curves of Japanese mackerel in this study were compared with those of Japanese mackerel from the Pacific group studied previously using F-test [29]. The results showed that there was no significant difference between the growth curves derived from the otolith age identification and the equations of the production curves of Japanese mackerel from different seas (Table 2, Figure 5). Therefore, it can be seen that the age identification of the present study has high reliability.

Comparing the results of the present study with the results of the growth equation parameters of Japanese mackerel in Japan’s coast (Table 3) derived by Kawashima, Tokuei and others, we found that the limiting fork length L_∞ of Japanese mackerel in the North Pacific high seas was higher than the results of

Tokifusa [29] and Iizuki [30], but similar to the results of Keiichi [31]. The K and t₀ values in this study were small among all studies, which proved that the growth and development of Japanese mackerel in the North Pacific open sea were slower than those on Japan’s coast.

The growth rate of fish reflects how fast or slow the fish increases in length or weight throughout its life. After understanding the growth rate of fish in each life stage, the period of fast growth to slow growth can be appropriately selected and utilized to maximize the fishery resources [21]. Wang Kai et al. analyzed the fishery resources of Japanese mackerel in the East China Sea according to the B-H (Beverton-Holt) dynamic integrated model, and suggested that the age at harvesting was 1.22 years old and the fork length at harvesting was 247 mm [7]; Liu Yong et al. studied that the inflection point age of Japanese mackerel in the north of the east China sea and the south of the yellow sea is 2.7 years, the inflection point weight is 450 g, and the inflection point fork length is 320 mm [3]. In this study, the inflection point age of Japanese mackerel in the high seas of the Northwest It can be seen that there are some differences in the growth process of Japanese mackerel population in different sea areas and different ages, and the age of inflection point of Japanese mackerel tends to become larger with the increase of latitude. In fishery, the fishing standard can be formulated comprehensively with reference to a series of factors such as growth characteristics, natural mortality, fishing mortality, environmental factors, space-time conditions, utilization rate of dominant groups and economic benefits [3] [21]. Finally, combined with the data obtained in this paper, we recommend 2 years of age to be start fishing with a fork length of 250 mm (±10 mm). This suggestion will provide a biological reference for the follow-up resource assessment and fishery management of Japanese mackerel in the high seas of the Northwest Pacific.