1. Introduction
The main target of the investigation of the marine resources is to give new information on the biology and dynamics of the explored populations, by knowing the life cycle and biological characteristics (e.g., recruitment, spawning biomass and fishing mortality) of the species, in order to determine the real conditions of those resources (Piñeiro, 2011) [1]. Two important nursery areas for European hake have been identified north-east Atlantic waters (ICES, 1996) [2]: one area is located off the French coast in the Bay of Biscay and is known as “Le Grand Vasiérè” and another one is in the Celtic sea between the south-west of England and southeast of Ireland; there is no such information for Portugal.
Several technical measures are taken to manage the stocks status. In Portugal those management measures are based on information given by the National Biological Sampling Program, co-financed by the EU within the Data Collection Framework (PNAB-DCF), on the landing composition (by sampling at the fish market), discards at sea (with scientific observers on board commercial vessels) and biology (from biological sampling at the laboratory). Indices of abundance and recruitment are obtained by the research surveys (acoustics, demersal and crustaceans) carried out by IPIMAR (Instituto de Investigação das Pescas e do Mar).
Hake in Portuguese coast is caught mainly by the polyvalent fishing (hooks and purse seine) and trawl, together with some other species of fish and crustaceans: horse mackerel (Trachurus trachurus), monkfish (Lophius spp.), megrim (Lepidorhombus spp.), chub mackerel (Scomber colias), Atlantic mackerel (Scomber scombrus), blue whiting (Micromesistius poutassou), shrimp (Penaeus spp.) and Norway lobster (Nephrops norvegicus). An important feature about hake is the fact that most of the larger individuals are landed gutted because ovaries get a very high price at the fish market.
In Portugal hake is studied since the middle of the 1960 decade (Monteiro and Dias, 1965 [3]; 1966 [4]) and several papers have been produced since then regarding many different areas, much of them related to abundance and distribution of adults, eggs and larvae (Cardador, 1995 [5]; Ibaibarriaga et al., 2007 [6]), fisheries, stock assessment and selectivity (Campos and Fonseca, 2003 [7]; Cardador, 1988 [8], 1991 [9]; Dias and Cunha, 1984 [10]; Fonseca et al., 2005 [11]; Moura and Cardador2005 [12]; Santos et al., 2002 [13]) and recruitment (Caramelo, 1983 [14]; Cardador et al., 2005 [15]; Mendes et al., 2008 [16]). Although in the beginning of the eighties years Marecos et al. (1982) [17] have developed some work on age and growth of the Portuguese hake, only later the biological study of the species increased, with particular interest on age and growth (Godinho et al., 2001 [18]; Jardim et al., 2004 [19]; Salgado et al., 2003 [20]) and maturity (Costa et al., 2009) [21], with special reference to the first microscopic maturity scale proposed by Gonçalves et al. (2004) [22] for the portuguese component of the Southern stock of hake, similar to the one used by IEO (Instituto Español de Oceanografía) that also studies the same hake stock, and implemented to distinguish correctly immature from resting females (Costa and Gonçalves, 2009 [23]; Costa et al., 2009 [21]), which are, as for many other species, not possible to distinguish macroscopically (Domínguez-Petit, 2007 [24]; Saborido-Rey and Junquera, 1998 [25]). Some other subjects have also been studied by Portuguese researchers, like parasites (Marques, 1985 [26]; Silva, 1984 [27]), feeding (Cabral and Murta, 2001 [28]; Hill and Borges, 2000 [29]) or lipid content (Gonçalves et al., 2004 [30]).
In the bibliography there are no references to important issues on the Portuguese hake, such as, sex ratio, physical condition or length-weight relationships. Therefore, the aim of this paper is to present the results of a biological study on the reproduction of the hake of the Portuguese coast for the last six years, based on the length distribution of captured fish, sex ratio, total length-total weight and total length-gutted weight relationships and the conversion factor between total and gutted weights. The somatic condition of the individuals was assessed by the condition factor, the gonadosomatic and the hepatosomatic indices and the spawning season was identified by the annual evolution of the maturity stages and the monthly changes in the gonads weights.
2. Materials and Methods
This work reports the results of the analysis of a 6-year time series (January 2005-December 2010) of some of the biological parameters that characterize the physical condition and reproduction of the Portuguese hake.
Our study was based on two sources of data:
1) random samples collected from landings at 12 fishing ports distributed by the portuguese NUTS II: Matosinhos and Póvoa do Varzim (North), Aveiro and Figueira da Foz (Center), Nazaré, Peniche, Sesimbra and Setúbal (Lisbon and Tagus Valley), Sines (Alentejo), Portimão, Olhão and Vila Real de Santo António (Algarve), which location is shown in Map 1.
2) samples collected by IPIMAR technicians on board
Map 1. Geographical distribution of the portuguese fishing ports where hake biological sampling was carried out in the period 2005-2010..
of commercial vessels operating in this sea area, in order to obtain information on the smaller individuals rejected to the sea by the fishing fleet.
In total 8212 samples were collected and after being screened to exclude those presenting sampling errors, such as total weight lower than gutted weight, 4935 were analysed. Given the large amount of information, impossible to present entirely in this kind of work, annual data were pooled by month and dealt by sex and by combined sexes, since hake stock assessment is based on combined sexes.
The number of individuals caught by year and the correspondent length range is presented in Table 1.
When possible the data collected from each sample were: total length (cm), total and gutted weight (g), sex, maturity stage and gonad weight (0.1 g). Since many of the fish over 40 cm are usually gutted, total weight, sex, maturity stage and gonad weight of 1395 individuals were not recorded. Data were pooled by month.
Weight-length relationships were estimated by fitting an exponential curve, W = a Lb, to the data (Ricker, 1973 [31], 1975 [32]). Weights and total lengths were logtransformed and the parameters a (the initial condition factor) and b (the allometric coefficient) of the W-L relationships were estimated by linear regression analysis, using the least-squares method. The degree of association between the variables W and L was calculated by the coefficient of determination (R2). The conversion factor for gutted to total weight was also calculated by forcing the linear relationships through the co-ordinates origin.
For fish with all data, total, gutted and gonad weight, the condition factor (CF), the gonadosomatic index (GSI) and the hepatosomatic index (HSI) were also calculated, in this way: CFt = Wt/L3 * 100 and CFg = Wg/L3 * 100 (Fulton, 1902) [33]; GSIt = Wgon/Wt * 100 and GSIg = Wgon/Wg * 100; HSIt = Wliv/Wt * 100 and HSIg = Wliv/Wg * 100 (West, 1990) [34], where CFt = condition factor obtained with total weight, CFg = condition factor obtained with gutted weight; GSIt = gonadosomatic index obtained with total weight, GSIg = gonadosomatic index obtained with gutted weight; HSIt = hepatosomatic index obtained with total weight, HSIg = hepatosomatic index obtained with gutted weight; Wt = total weight (g), Wg = gutted weight (g), L = total length (cm), Wgon = gonad weight (g), Wliv = liver weight (g). Condition factor, gonadosomatic and hepatosomatic indices were analysed by sex and within each sex the individuals were also split into immature and mature. Females were considered to be immature with less than 38 cm total length and males were considered immature with less than 26 cm total length, based on the mean of the L50 calculated for the years from 2006 to 2009 from the individuals obtained with visceras (Costa et al., 2009) [21].
Conversion factors between gutted and total weights were calculated by sex for all fish sampled.
The weight of the viscera was calculated by sex, as a percentage of the total weight. The spawning season was estimated by studying the percentages of maturity stages assigned de visu to each specimen, based on the macroscopic maturity scale key for hake (ICES, 2007) [35] (Table 2) along with the ovary weight and the obtained GSI and HSI.
3. Results and Discussion
Although the studied period started in January 2005 and finished in December 2010, to understand the importance of this species along the years, the hake landings and fish auction market price were analysed for the all decade (2000-2010) and are presented in Figure 1.
The annual length distribution of sampled hake landed by the different fishing gears in the studied period is shown in Figure 2.
Total lengths of fish sampled ranged from 7.3 to 93.3 cm, with 49.8% of the fish belonging to 30 to 50 cm length. Total length of females ranged from 20.0 cm (with 44.0 g weight) in April, to 82.8 cm (with 5304.0
Figure 1. Mean catches and mean market value of hake in the decade 2000-2010. The values correspond to the means of the different fishing gears operating at the twelve ports studied (source: DGPA, 2000 to 2010 [105 - 115]).
Table 1. Number of M. merluccius caught during 2005-2010 in the Portuguese coast.
Table 2. Hake macroscopic maturity stages (ICES, 2007).
Figure 2. Annual length composition of hake sampled during the period 2005-2010.
g weight) in July. Total length of males ranged from 20.0 cm (with 46.0 g weight) in April to 66.1 cm (with 2057.9 g weight) in May. Fish smaller than 25 cm length, with high numbers in 2005, decreased greatly in the samples of 2006, but from 2007 onwards their abundance raised and in 2010 the number of fish sampled with less than 25 cm was very high. The number of sampled fish bigger than 55 cm length was in general low in all the years.
Fish smaller than 20.0 cm length were not sexedwhatled to a total of 5215 fish macroscopically sexed (3592 females and 1623 males). Individuals whose sex assign ment presented doubts were not considered. Most of the fish sexed belonged to length range 20 - 30 cm (86.8%) and 30 - 40 cm (91.5%), showing a sex ratio close to 1:1 (Figure 3). In length classes bigger than 40
Figure 3. Sex ratio for hake in the Portuguese coast in the period 2005-2010.
cm the proportion of fish sexed was smaller but there was a high predominance of females, in particular among the individuals over 50 cm length (97.3%).
3.1. Length-Weight Relationships
The relationships between total length and total weight were determined for both sexes by month in a total of 5471 specimens (1889 males and 3582 females). The estimated parameters of the total length-total weight relationships, the number of fish, length and weight ranges and the correlation coeficients are presented in Table 3 (years are pooled by month).
The same parameters were estimated for the total length-gutted weight relationships, with a total of 6657 fish, which are presented in Table 4. In this table, where
Table 3. Monthly total length-total weight relationships for hake in the Portuguese coast for the period 2005-2010 (years are pooled by month).
Table 4. Monthly total length-gutted weight relationships for hake in the Portuguese coast for the perid 2005-2010 (years are pooled by month).
years are pooled by month, the values of sexes combined were obtained not only with the sexed fish but also with the adult fish (over 20 cm length) landed already gutted.
The total length and weights relationships for the total individuals sampled and by sexes are shown in Tables 5 and 6.
Length-weight relationships were statistically compared to determine whether there were differences in growth rate between males and females, considering the same length ranges for comparison. The results seem to indicate that the annual growth is similar for males and females (Table 7).
In Table 8 are shown the monthly relationships between total and gutted weights for males, females and sexes combined, the length and weight ranges, number of fish sampled and the correlation coefficient obtained (years are pooled by month).
Grouping together the monthly values of total and gutted weights the relationships found are: Wt = 7.0261 + 0.892Wg for males, Wt = 16.3313 + 0.845Wg for females and Wt = 15.8112 + 0.848Wg for sexes combined.
Considering the same length ranges, total weightgutted weight relationships were also statistically compared for both sexes, showing that the annual growth is different for total weight and gutted weight (Table 7).
According to these results the growth rates of males and females are similar for both sexes although higher when calculated with total weight than with gutted weight.
Conversion factors between gutted and total weights are presented in Table 9.
Grouping together the monthly conversion factors between gutted and total weights the values obtained are: 1.0980 for males, 1.1585 for females and 1.1524 for sexes combined.
As seen in the Figure 4, and particularly in females, in the length classes over 30 cm viscera represent more than 10% of the total weight and more than 15% in length classes over 60 cm. Considering the mean weight of all length classes viscera account for 13.28% of total weight. The monthly evolution of the visceras weights show for both sexes an increasing trend from January to August, then decreasing until November rising again in December, particularly in females.
3.2. Somatic Condition
Condition factor (Fulton factor) was calculated with total weight (TW) and gutted weight (GW). Mature females (³38 cm) showed always higher values than immature females (<38 cm) during the entire period, with a similar but smoother oscillation (Figure 5).
Both immature (<26 cm) and mature males (³26 cm) didn’t show high variations of this index along the year.
The gonadosomatic index, obtained either with the total weight (TW) or the gutted weight (GW), showed the same general pattern for males and females along the year (Figure 6). The values of both indices for females were about 3 times higher of the values of the same indices for males. Immature and mature females showed an opposite variation of GSI during the first semester but in the second half of the year the variation was similar for all the females. Due to the lack of samples this comparison could not be done for males.
The monthly evolution of the hepatosomatic index obtained with the total weight (HSIt) and the gutted weight (HSIg) was similar for mature and immature fish, with the HSIg values slightly higher (Figure 7). Females’ maximum values of these indices were found in the beginning of the 4th quarter (October) while mature males (³26 cm) showed a sharp increase in June.
For both sexes the Pearson coefficient (r) shows stronger correlations (Cohen, 1988) [36] between GSI and CF or HSI when using gutted weight (Table 10). With total weight those relationships are in general medium and between HSI and CF they are weak, either for males or females.
Table 5. Total length-total weight relationships for hake in the Portuguese coast for the period 2005-2010.
Table 6. Total length-gutted weight relationships for hake in the Portuguese coast for the period 2005-2010.
Table 7. Statitical analysis of the growth rate of Portuguese hake.
3.3. Spawning Season
The annual evolution of the maturity stages is a good indicator of the spawning period of a species.
The analysis by sex of the proportion of each maturity stage along the year (Figure 8) shows that immature females were present in higher proportions than immature males in every month. In the mature stages (2, 3 and 4) males were in general present at higher proportions, except for maturity stage 3. The months with the highest proportion of mature stages were May for females (74%) and November for males (94%). Considering both sexes May showed the highest proportion of mature stages (76%).
Another indicator of the spawning season is the monthly evolution of the ovary weight (Figure 9).
In this graphic the 4 peaks of higher ovaries weights (averages) are signalised (sp.) and interpreted as “spawning peaks” and the ascending lines are considered as following recovering periods. Although 2727 ovaries were weighted, the low values observed in December and January are probably due to an insufficient number of individuals sampled (7 and 123, respectively), while in the rest of the year a mean of 260 ovaries were weighted per month.
According to the length class, females spawn mainly three times per year, in January-March, May-June and August, as shown in Table 11. These observations seem to indicate that the start of the spawning is independent of fish length, since the spawning peaks occur at the same time for all the fish lengths. The ascending lines shown in the previous figure in October, November and December may represent only false spawning peaks, due to the small number of individuals analysed in those months.
Another fact that can be observed is the increase of the weights of the ovaries with length, which can be explained since normally the gonads are bigger on bigger exemplars.
4. Discussion
One of the most important and exploited fish species in western demersal fisheries is the european hake (Merluccius merluccius L., 1758) (Casey and Pereiro, 1995) [37], not only due to its high abundance and large distribution but also because of its role in the food chain. Since 1978 the ICES Working Group on the Assessment of Southern Shelf Demersal Stocks (WGSSDS) distinguishes two hake stocks for assessment purposes: the northern stock and the southern stock (ICES, 1979) [38]. Both stocks are outside safe biological limits and EU has developed in 2006 a recovery plan for the southern stock of this species (EU, 2011) [39]. Taking this into account, the administration authorities need cientific advice to ensure the sustainable management of those species, in order to protect the spawning stock. Therefore, in particular during the spawning season, management measures must be taken, which may consist of seasonal bans, the reduction of fishing effort and the update of the estimation of length at first maturity (L50), since this parameter can change as a result of the fishing intensity or exploitation pattern (BIOSDEF, 1998) [40]. One of the most important management measures for a certain species is the establishment of its minimum landing size, along with the obligation of discarding to the sea all the individuals with smaller sizes. In order to have a biological meaning this minimum size must allow the individuals to reach the size of reproduction, but it must also take into account the characteristics of the fishing gear that captures that species, in other words, its selectivity. The Council Regulation (EC) No. 850/98 of 30 March 1998 established for the european hake the minimum landing size of 27 cm.
Due to the economical importance of hake there are abundante studies about several subjects, such as, biology, maturity, fecundity, reproduction, distribution and growth, not only on the species Merluccius merluccius (Biagi et al., 1995 [41]; de Pontual et al., 2006 [42]; Domínguez-Petit et al., 2008 [43]; El Habouz et al., 2011 [44]; Korta et al., 2010 [45]; Murua and Motos, 2006 [46]; Murua et al., 1998 [47]; Piñeiro and Sainza, 2003 [48]; Velasco and Olaso, 1998 [49], among others) as on the other species of Merluccius (e.g. Balbontin and Fischer, 1981 [50]; Fernández-Peralta et al., 2011 [51]; Honji et al., 2006 [52]; Relini et al., 2002 [53]). Although in Portugal there has been a directed trawl fishery for white hake for many years and substantial quantities are catch with different fishing gears, biological investigations have been rather limited. Thereby, in the present study some parameters are presented and discussed in order to clarify some characteristics related to the biology of Merluccius merluccius that inhabits the waters along the portuguese coast.
Regarding the length distribution of hake along the years, fish smaller than 25 cm, present in 2005, almost desappeared in 2006, increasing again in 2007, what might be explained by the fluctuations of the recruitment indices in those years. The oscillations in hake catches are not a portuguese problem in particular. Since the 1960s (FAO, 2010) [54] European hake catches have been decreasing and the commercial viability of aqua
Figure 4. Percentage of viscera weight on the total weight by length class and by month of hake in the Portuguese Coast in the period 2005-2010. Females-length classes 73, 75, 76 e 82 cm with only 1 fish. Males-length classes 55, 57, 59 e 66 cm with only 1 fish.
Figure 5. Condition factor monthly evolution using the total and gutted weight for hake in the Portuguese coast in the period 2005-2010.
Figure 6. Gonadosomatic index monthly evolution calculated using the total and gutted weight for hake in the Portuguese Coast in the period 2005-2010.
Table 8. Monthly total weight (Wt)-gutted weight (Wg) relationships for hake in the Portuguese coast for the period 2005- 2010 (years are pooled by month).
Figure 7. Hepatosomatic index monthly evolution calculated using the total and gutted weight for hake in the Portuguese Coast in the period 2005-2010.
Figue 8.. Maturity stages assigned de visu for females (left) and males (right) hake in the Portuguese Coast in the period 2005-2010. Maturity stages: 1) Immature or Resting; 2) Maturing; 3) Spawning; 4) Post-spawning.
Table 9. Conversion factor for gutted weight (Wg) to Total Weight (Wt) by sex and by month for hake in the Portuguese coast in the period 2005-2010 (years are pooled by month).
Table 10. Pearson correlation coeficient of GSI, HSI and K for hake of the Portuguese coast calculated using the total and gutted weight in the period 2005-2010.
Table 11. Peaks of hake spawning in the Portuguese coast in the period 2005-2010.
Figure 9. Monthly evolution of average ovarian weight of hake in the Portuguese Coast in the period 2005-2010 considering all the length classes.
culture production has recently increased (Groison, 2010 [55]; Hiney et al., 2002 [56]; Kjesbu et al., 2006 [57]). some researchers have even stated that the hake is one of the most promising new species for marine aquaculture (Engelsen et al., 2004) [58]. Recruitment indices of hake in the portuguese coast have been varying in the last decades, showing a decreasing trend from 1990 to 1995, followed by a strong oscillation from 1995 onwards (Cardador et al., 2009) [59]. Maybe this is responsible for the decreasing catches verified at the middle of the 2000 decade. However, the recovery plan for the southern stock of hake implemented by the E.U. in 2006, as well as the ban on fishing in the portuguese waters between Milfontes and Arrifana, from the 1st of December to the last day of February for the protection of the juveniles, are most likely contributing to the increase of the abundance indices in the most recent years—an increase of 65% in 2007 compared with the previous years. Unlike juveniles, that distribute between 100 and 200 meters depth (Cardador et al., 2009) [59], bigger individuals, living at higher depths, are always caught in smaller numbers. In the present study fish with more than 50 cm total length corresponded to 19% and those with more than 60 cm corresponded to 5% of all the sampled specimens. Yet, these numbers may not reflect the size structure of the exploited population since the discards of the species Merluccius merluccius were very high in the years 2004-2005, 18% (Fernandes et al., 2008) [60], while in 2007-2008 the discards of hake, mainly of individuals smaller then 27 cm (the legal minimum length) were higher then the species landings (Cardador et al., 2009) [59].
Similar observations are referred by Lucio et al. (1998) [61] for the Bay of Biscay, where only 10% of the captured fish were 45 - 49 cm and less than 5% had more than 60 cm. Piñeiro et al. (1998) [62] also mention that very few individuals were caught with more than 60 cm in the ICES Div. VIIIc and IXa.
In the present study sex ratio for the length classes smaller than 40 cm was close to 1:1. In the individuals over 40 cm length females were predominant (1:0.13) while in the classes over 50 cm the abundance of females almost reached the 100% (1:0.03). The several authors that refer the sex ratio of the different hake populations present, in some cases, results different from ours, stating that in length classes under 40 cm males are predominant. Piñeiro et al. (1998) [62], Sainza and Pérez (1998) [63] and Lucio et al. (1998) [61], studied the biology of demersal fish of the Bay of Biscay and the Cantabrian Sea, within the project BIOSDEF, and refer that in the length classes 25 - 45 cm prevailed the males, while in length classes 45 - 55 cm the proportion of the two sexes was of 1:1. A similar result was observed by Piñeiro and Sainza (2003) [48] in Iberian Atlantic waters corresponding to ICES divisions VIIIc and IXa for the individuals under 45 cm length, but for the bigger classes observations were slightly different, with the males outnumbering the females, after which females predominated and rapidly increased in relative abundance to reach 100% in fish larger than 60 cm. Also El Habouz et al. (2011) [44], working with hake from the eastern central Atlantic, refer that the evolution of the sex ratio in the length class interval 17 to 45 cm was close to 1:1 and that only females were found over 45 cm length. Higher number of males for intermediate sizes and higher number of females for larger sizes has been observed by Fariña and Fernández (1986) [64] in the West of Ireland, in the Portuguese coast by Portuguese researchers during five years of surveys (ICES, 1982 [65], 1983 [66], 1986 [67], 1987 [68], 1988 [69]), as well as in the bay of Biscay by Martin (1991) [70] and Lucio et al. (1998) [61]. Sarano (1983) [71] states that in the Gulf of Gascony most of the smaller individuals were males, while the bigger fish were predominantly females. Finally, Angelescu et al. (1958) [72] show a proportion of 2:1 in favor of the females of the Argentine Sea. Despite these different observations, the results of all the authors indicate, just like ours, that in length classes over 60 cm the percentage of females reaches almost the 100%. This can be due to the differences in the growth rates of the two sexes, the natural mortality rate of old males may be much higher than that of females or to the different behaviour and consequently different acessibility of fish (Piñeiro, 2011) [1]. Likewise, if male grow at a smaller rate, particularly after the start of reproduction the effect of growth and the mortality rate at length would lead to a bigger percentage of females at bigger length (Martin, 1991) [70]. Indeed, a recent study of the growth of European hake using tagging and recapture techniques (Mellon-Duval et al., 2010) [73] shows that from the second year of life, females grow faster than males.
The allometry coefficient is expressed by the exponent b of the linear weight-length relationship equation. This relationship reflects an isometric growth when b = 3, i.e., when the relative growth of both variables is perfectly identical (Mayrat, 1970 [74]; Ricker, 1973 [31], 1975 [32]). If b < 3 we are in presence of a negative allometric growth and if b > 3 we have a positive allometric growth (Sokal and Rohlf, 1987) [75]. In general, the estimates of length-weight relationships obtained in this study, based either on the total weight or the gutted weight, are close to those obtained by other authors in previous studies, not only for the portuguese coast but also for the adjacent areas of hake distribution (Cardador, 1988 [8]; Cardenas and Fernández, 1981 [76]; Godinho and Afonso, 1998 [77]; ICES, 1991 [78]; Lucio et al., 1998 [61]; Morey et al., 2003 [79]; Moutopoulos and Stergiou, 2002 [80]; Piñeiro et al., 1998 [62]; Piñeiro and Sainza, 2003 [48]; Santos et al., 2002 [13]). Most of the results reported are related to the relationships between total length and total weight and to both sexes combined. Only few authors present these relationships between total length and gutted weight and with reference to males and females separately (Godinho and Afonso, 1998 [77]; Lucio et al., 1998 [61]; Piñeiro and Sainza, 2003 [48]; Piñeiro et al., 1998 [62]). We also could not find any reference to these relationships on a monthly basis, which we consider to be important since the gonads weights, mainly the ovaries, may vary considerably according to the time of the year, in particular along the spawning season, when the ovaries undergo a high increase in weight. Other factors, such as food availability on fish growth (Mommsen, 1998) [81], spatial variation due to the influence of water quality (Sparre et al., 1989) [82] or feeding rate (Santos et al., 2002 [13]) can also affect the length-weight relationships. However, the parameter b is characteristic of the species (Mayrat, 1970) [74] and generally does not vary significantly throughout the year, unlike the parameter a, which may very daily, seasonally and/or between different habitats (Bagenal and Tesch, 1978) [83]. So, we conclude that the observed differences with the values reported in other studies can be due to differences in the number of samples at length distribution margins, by the time of the year when sampling took place or to the selective characteristics of fishing gear. The conversion factor between gutted and total weights found in our study is of the same kind of the ones presented by Cardenas and Fernández (1981a) [84] for the ICES Divisions VIIIc and IXa and by Lucio et al. (1998) [61] for the Bay of Biscay in particular.
The condition factor gives a general idea of the body condition, in terms of weight, of the fish along the year. The results of the present study, similar to the results presented by other authors (Lucio et al., 1998 [61]; Murua, 2006 [85]; Pérez and Pereiro, 1985 [86]) seem to show that hake condition, considering either the total or the gutted weight, is higher in autumn (November/December), decreasing in winter and reaching its minimum in spring (April). The general pattern observed, similar for both sexes, although for males with less marked fluctuations, maybe due to the fact that in females there is a higher transfer of energy, expressed in terms of weight, to the development of the ovaries.
There are several indicators that, along with the condition factor, allow us to define the spawning season of a certain species, including the indexes of the somatic condition (GSI and HSI), the annual distribution of the maturity stages and the gonads weight. In the present study the distribution of the maturity stages along the year, in particular the occurrence of maturity stages 2 (maturing) and 3 (spawning), as well as the annual distribution of the gonads weight, seem to indicate that spawning lasts from January to August, although with several peaks. Gonadosomatic index expresses the maturity of the gonads and its higher values indicate that the gonads are developing, while its lower values indicate the end of the spawning period (Lahaye, 1972) [87]. During maturation the fat reserves accumulated in the liver during the HSI peaks are mobilized to the ovaries oogenesis and the hepatosomatic index decreases rapidly (Billard, 1979 [88]; Lahaye, 1972 [87]). In the present study, although this observation is not very clear, an increasing trend of the GSI can be seen along the first semester, while HSI showed a decreasing tendency. These observations are in accordance to the fact that the European hake is reproductively active for almost the entire year and spawning females are found all the year round (Murua and Motos, 2006) [46] and so the annual evolution of the two indexes is not as clear as in species with a shorter spawning season (El Habouz et al., 2011) [44].
The analysis of the total results of this study and considering the presence of maturity stage 1 (Immature or Resting), present throughout the year, and the monthly distribution of the weights of the gonads, it seems that the hake of the portuguese coast has a long spawning season, but where three stronger spawning peaks seem to be identified, March, May and August, and a weeker one in October. The same results are presented by Monteiro and Dias (1965) [3], who refer that female hakes from the Portuguese coast spawn all year around, with a higher intensity in Spring and Summer. Similar observations are pointed out by other authors that refer a long spawning season for the species Merluccius merluccius, as well as the presence of individuals mature and immature throughout the year (Al-Absawey, 2010 [89]; El Habouz et al., 2011 [44]; Piñeiro and Sainza, 2003 [48]). The winter spawning season has been observed previously in the Moroccan Atlantic (El Habouz, 1995 [90]; Ramos et al., 1990 [91], 1991 [92]), while Maurin (1954) [93] refered for the same area a longer spawning season, from December to the beginning of summer. Two peaks have also been observed in winter and summer in the CECAF area (Cervantes and Goñi, 1986) [94], January-February, and a secondary peak in summer, July-August, while a maximum spawning peak was observed from January to March on the north Atlantic Spanish coast (Perez and Pereiro, 1981 [95]) Piñeiro and Sainza, 2003 [48]) and in the Bay of Biscay (Murua and Motos, 2006 [46]). In the Mediterranean Sea, Bouhlal (1973) [96] observed a maximum spawning peak in winter and two othersmaller peaks in spring and late summer in the Gulf of Tunis, while Álvarez et al. (2001) [97] refer for the NE Atlantic that the spawning season extends from February to July. Other studies into the reproductive biology of European hake have indicated that this species spawns from January through July, along the shelf edge from the Bay of Biscay to the southwest of Ireland (Álvarez et al., 2004 [98]; Lucio et al., 2000 [99]; Martin, 1991 [70]). Other species of Merluccius, living in other geographical areas, also present long spawning seasons. M. hubbsi Marini, 1933, from the Patagonian waters, spawns from December to March, with a peak in January-February (Macchi et al., 2004 [100]); the spawning season of M. productus Ayres, 1855, from Canada, extends from February to June (Mason, 1986 [101]), while the results of Payá and Ehrhardt (2005) [102] and Landaeta and Castro (2012) [103] studying M. gayi gayi Guichenot, 1848 and M. australis Hutton, 1872, from the Chile indicate that the spawning season lasts from late summer to early autumn. In the NW Pacific M. albidus Mitchill, 1818, spawns from April to July (Traver et al., 2012 [104]). M. senegalensis Cadenat, 1950 and M. polli Cadenat, 1950, also called black hakes, are two species which distribution area overlaps with the European hake M. merluccius and which spawning season lasts from November to February (Fernández-Peralta et al., 2011 [51]).
This study addresses a set of reliable parameters that can be used to undertake new assessments filling the gap of information available on the reproductive biology of European hake inhabiting the Portuguese coast. After a detailed analysis we did not find significant differences in relation to the results presented by other authors, either for the Iberian Peninsula or the adjacent areas. This work can therefore be the basis for the development of other fields of study, more delimited in space or in time.
5. Acknowledgements
This work was supported by the PNAB/EU DCR-Data Collection Regulation. The author is grateful to Doctor Alberto Murta for his help with statistical analysis and all the technicians that along these years have performed the biological sampling that made this work possible.