Department of Marine Biology, Faculty of Biological Science, Shahid Beheshti University, Tehran, Iran
Received date: March 17, 2013; Accepted date: May 21, 2014; Published date: May 29, 2014
Citation: Hosseini M, Pazooki J, Safaei M (2014) Size at Maturity, Sex Ratio and Variant Morphometrics of Blue Swimming Crab Portunus segnis (Forskål,1775) from Boushehr Coast (Persian Gulf). J Marine Sci Res Dev 4:149. doi:10.4172/2155-9910.1000149
Copyright: © 2014 Hosseini M, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Visit for more related articles at Journal of Marine Science: Research & Development
Size at maturity, sex ratio and variant morphometrics of blue swimming crab Portunus segnis was studied for one year along the Persian Gulf coasts, Iran. Sex ratio during a year of study was M:F=0.92:1 which should be the relative frequency of females. Male blue crabs have a V-shaped abdomen and female have an abdomen broad and rounded. The carapace width/length- weight relationship was studied in both sexes of crab. The allometric relationships between the characters of this set suggest that most relationships are positive and highly significant. An analysis of covariance indicates that there is a significant difference between sexes with respect to the carapace width-weight relationship. The crab’s carapace widths ranged were from 75 to175 mm for males and 70 to170 mm for females. The crab’s carapace lengths were from 35 to 80 mm for male and 30 to 80 mm for female. The results of this study show that at the same size, weight and the parameters of carapace length and carapace width male of Portunus segnis are higher than females in Persian Gulf coasts.
Size at maturity; Sex ratio; Portunus segnis; Persian Gulf
Crabs belong to a group of animals knows as brachyura crustaceans. Most of the marine crabs occurring along the Persian Gulf coasts belong to the family Portunidae. The blue swimming crab Portunus segnis is distributed from the eastern Mediterranean to east Africa in the Indian Ocean, and to Pakistan, Red Sea and Persian Gulf . Also live in a wide range of inshore and continental shelf areas, including sandy, muddy or algal and sea grass habitats, from the intertidal zone to at least 50 m depth. They are usually found in large numbers in shallow bays with sandy bottom and are important commercial species is Iran and South East Asia [2-4].
This species supports substantial commercial fishery in the Persian Gulf and is an important component of many recreational fisheries in Iran and other parts of the world and the major species crab caught in trawl nets. They have five paired legs (ten legs), some of the legs are pointed and others flat. The pointed ones are used for crawling and the flat ones are used like paddles for swimming. The first pair of legs, which are modified as claws, called chelipeds. The cheliped are long, elongated ridged, catch and hold food and bring it to the mouth, digging, cracking open shells and warning off would be attackers. At the same size, males are heavier than females in the coasts of Persian Gulf.
In crustaceans, as growth progresses, certain dimensions of the animal’s body may grow much more than others, resulting in the phenomenon known as relative growth . Studies of relative growth are often used to determine changes in the form and size of the abdomen, pleopods, or chelipeds during ontogeny. Knowledge of these distinguishing characters and size relationships in sexually mature individuals is of particular importance in the study of commercially valuable crustaceans. Such knowledge can be useful for further studies on the life history of the species and in the development of its fishery, resource management, and culture. The mathematical length-weight relationship thus yields information on the general well-being of individuals, variation in growth according to sex, size at first maturity, gonadal development, and breeding season. Study of the length-weight relationship in aquatic animals has wide application in delineating the growth patterns during their developmental pathways .
In population studies, morphometric analysis provides a powerful complement to genetic and environmental stock identification approaches and length-weight relationships allow the conversion of growth-in-length equations to growth-in-weight for use in a stock assessment model . Information about individual body weightlength/ width relationships in populations is important for estimating the population size of a stock, specifically for the purpose of its exploitation. The length-width/weight relationships are regarded as more suitable for evaluating crustacean populations [7-12]. The interrelationships between various morphometric characters, carapace width and length and chelar propodus length, and abdominal width in females and males, were analysed and are here presented. The results will be useful in comparing the different stocks of the same species at different geographical locations.
The study was carried out in coasts of Boushehr, which is one of the several adjoining coasts in the Persian Gulf (Figure 1). The Persian Gulf lies on the south Iran, between longitudes 48°25’ and 56°25’ East, and latitudes 24°30’ and 30°30’ North. It has an estimated area of 260 km2 and extends 909 km long to a depth average of about 30-40 m. Specifically, the Boushehr lies between Longitudes 50°6’ and 52°58’East and Latitudes 27°14’ and 30°16’ North and it is about 60 km long .
Sampling was performed in Persian Gulf coast (Boushehr province) including stations four along the Buoshehr coasts .The crabs for study were collected seasonal for one year from January 2011 to December 2011. Sampling was performed with several methods such as trawl net, research ship. After sampling, samples were taken to the laboratory in a cooler and stored in a deep freezer for further analysis. Then the crabs are washed for removing the mud and algae’s and barnacles sticked to the external skeleton. Crabs were identified to species level carried out using photo cards and available identification keys [7,8]. Therefore each crab was sorted into species. The first sex and their morphological characteristics (Wet weight, carapace width and carapace length, width and length of the abdomen and chelar (propodus) length) were taken. Male blue swimming crabs have a V-shaped abdomen and female crab have an abdomen broad and rounded . Vernier callipers with an accuracy of 0.5 mm were used for length measurements, and the total weight of the crab was determined to the nearest gram using a digital balance (1 g).
Carapace width (CW) was taken as the distance between the tips of the posteriormost lateral carapace spines. Carapace length (CL) was measured dorsally along the midline, between the frontal notch and the posterior margin of the carapace. Right chelar propodus length (Ch L) was measured from the tip of the propodus’ fixed finger to the base of the propodus. When the right chela was missing or damaged, the left chelar propodus length and height were taken, as in P. segnis both chelae are equally well developed. Abdominal width was measured at the maximum width, i.e., across the fourth somite. Abdominal length was measured along the midline from the anterior margin of the first somite to the posterior margin of the telson.
The carapace width-weight relationship was estimated using the log form of the allometric growth equation W=aLb , where W=expected weight, L=total carapace width, ‘a’=y-intercept or the initial growth coefficient, and ‘b’=the slope or growth coefficient. The values of constants of ‘a’ and ‘b’ were calculated by the least squares method. The differences in the carapace width-weight relationship between sexes were tested by ANOVA (MS Excel).
Data were presented as mean ± standard deviation. Appropriate measure of the size of maturity (CW50) in both males and females crabs size of maturity was determined when 50% of the crabs were sexually matured. CW50 was determined by using the linear regression at CW range that produced percentage of maturity at 50%.
Sex ratio during a year of study was M: F=0.92: 1 which should be the relative frequency of females. The crabs CW ranged were from 6.0 cm to 17.5 cm for males and 5.5 cm to 17.0 cm for females. The crabs CL were from 4.0 cm to 8.0 cm for male and 3.5 cm to 7.0 cm for female. The BW ranged from 40.0 to 275.0 gr for males and 32.50 to 242.2 gr for females (Table 1). The results of this study show that at the same size, BW and the parameters of CL, CW and CPL male P. segnis are higher than females in Persian Gulf coasts.
|Carapace width (cm)||6||17.5||5.5||17|
|Carapace Length (cm)||4||8||3.5||7|
|Total Weight (gr)||40.0||275.0||32.50||242.2|
Table 1: The morphological characteristics (carapace width, carapace length and total weight) of P. segnis.
A total of 448 female crabs of P. segnis of various sizes were randomly sampled and only 278 crabs of P. segnis had mature abdomen. The largest immature female encountered was 16.5 cm CW and the smallest mature female was 7.40 cm CW. Using the abdominal flap changes for female as an indicator of crab maturity, the percentage of female crabs that mature was calculated for each 0.5 cm CW interval from CW range of 6.0 cm (the smallest size range of the crab sampled) to CW range of 17.0 cm (the largest size range of the crab sampled). Using the linear regression at the CW ranges that shows percentage of maturity, CW50 occurred at7.5 cm CW in the female crabs with y=30.5x+10.5 and R2=0.9368 (Figure 2).
Out of 418 male crabs sampled, only 242 crabs of P. segnis were mature. Male crab maturity was determined based on the presence of enlarged and white vas deferens. The largest immature male encountered was 17.5 cm CW and the smallest mature female was 7.5 cm CW. Using the presence of vas deferens for male as an indicator of crab maturity, the percentage of male crabs that mature was calculated for each 0.5 cm CW interval from CW range of 6.0 cm (the smallest size range of the crab sampled) to CW range of 17.5 cm (the largest size range of the crab sampled). Linear regression analysis at the CW ranges that shows percentage of maturity, shows that the size at maturity, CW50 occurred at 8.24 cm CW in the male crabs with y=17.2x+0.8 and R2=0.9844 (Figure 3).
Allometric equations with respect to males and females of P. segnis are indicated in Tables 2 and 3. The allometric relation between the set of characters studied suggested that in most cases the relationship was positive and highly significant. The study has shown that males are marginally heavier than females up to 120-125 mm carapace width, and there after males are heavier than females. The scatter diagram for males and females was obtained by plotting weight against carapace width/length of individual crabs. From the data presented, a distinct relationship was found between width and total weight, as judged from the closeness of the scatter dots, as well as from the parabolic nature of the plot.
|Allometric growth equation
|Carapace width||Abdomen width||AW=−18.228+0.4563 CW||0.5567*|
|Carapace width||Abdomen length||AL=−16.442+0.7664 CW||0.3343*|
|Carapace Length||Abdomen width||AW=−15.232+0.6673 CL||0.7675*|
|Carapace Length||Abdomen length||AL=−6.664+0.5579 CL||0.4454*|
|Abdomen width||Abdomen length||AL=−7.886+0.7764 AW||0.7677*|
|Carapace width||Chelarpropodus length||CPL=−69.334+1.4676 CW||0.6777*|
|Carapace length||Chelarpropodus length||CPL=−58.665+1.7655 CL||0.3343*|
Table 2: Allometric equations and correlation coefficient (r) values between different variables in males of P. segnis.
|Independent variable (x)||Dependent variable (y)||Allometric growth equation (y=a+bx)||‘r2’ value|
|Carapace width||Abdomen width||AW=−17.008+0.7656 CW||0.6754*|
|Carapace width||Abdomen length||AL=−15.332+0.7334 CW||0.6884*|
|Carapace Length||Abdomen width||AW=−12.552+0.8873 CL||0.7332*|
|Carapace Length||Abdomen length||AL=−6.7764+0.8979 CL||0.6112*|
|Abdomen width||Abdomen length||AL=−5.6554+0.9884 AW||0.6442*|
|Carapace width||Chelarpropodus length||CPL=−59.556+1.5556CW||0.5221*|
|Carapace length||Chelarpropodus length||CPL=−51.225+1.4443CL||0.5546*|
Table 3: Allometric equations and correlation coefficient (r) values between different variables in females of P. segnis.
The exponential values (b) for the carapace width-weight relationship in males and females (2.334 and 2.554, respectively) show that there is marked deviation from the isometric growth pattern (Table 4). The ‘t ’ test confirmed that ‘b’ significantly differs from 3, in both sexes. The exponential values (b) for carapace length-weight in males and females (2.112 and 3.443, respectively) indicate that the significant departure from isometric growth is only evident in females. In males, the curve follows an isometric growth pattern. The ‘t’ values are given in Table 5.
|Measurements||Sex||Logarithmic equation||Parabolic equation|
|Carapace Width-Total Weight||Male||Log=−16.532+2.334 log L||W=0.00006469L3.552|
|Female||Log=−15.278+2.554 log L||W=0.00002233L2.443|
|Carapace Length-Total Weight||Male||Log=−6.551+2.112 log L||W=0.00005445L3.033|
|Female||Log=−5.720+3.443 log L||W=0.00003442L2.332|
Table 4: Carapace width/length-total weight relationship in males and females of P. segnis.
|Carapace Width-Total Weight||Male||18.22||Significant at 1% level|
|Carapace Width-Total Weight||Male||2.33||Significant at 1% level|
|female||6.51||Significant at 1% level|
Table 5: The ‘t’ values for the carapace width/length and total weight relationship in males and females of P. segnis.
The relationship between female abdomen width and CW. is shown in (Figures 4 and 5). The abdomen width shows positive allometry in the first phase (crabs <8.7 cm CW) and the allometry becomes more positive in the second phase (crabs >7.5 cm CW). Thus the size at which puberty molt occurs is between 7.1 and 8.0 cm CW.
The relationship between chelar propodus length and CW is shown in (Figures 6 and 7). for male crabs. In male crabs chela allometry is slightly positive in first phase (crabs having <7.5 cm CW) and then allometry changes and chela grows more positively in second phase (crabs having >8.7 cm CW). This shows that the puberty molt occurs between 7.5 and 8.7 cm CW in male crabs.
Sexual maturity is defined the ability to successful mate and results in the extrusion of fertilized egg . The pubertal molt stage in P. segnis is said to be a reliable indicator of the ability of female crab to mate. Studies have also shows that the female Portunus spp. molt again after the pubertal molt [12-14]. The result from the present study shows that the P. segnis male mature at a smaller size than female crab for both morphological appearances and relative growth.
Knowledge of the distinguishing characteristics and size relations of sexually mature individuals is of particular importance in the study of commercially valuable crustaceans. Crabs of the family Portunidae are distinguished by having the dactylus of their fifth pereiopods enlarged and flattened, which facilitates swimming. In the Indo-Pacific region, the genus segnis is represented by a member that has nine antero-lateral spines at each side of the carapace, the posteriormost one of which is enlarged. All these characters are in agreement with the descriptions of Portunus segnis. In addition, in this species sexes are easily differentiated by the colour pattern of their exoskeleton. Males are brilliantly coloured with bright blue, and females have a dull brown colour. This unique feature is not seen in other common portunids. Gross morphological differences in external anatomy between sexes are similar to those of other portunid crabs [11-15].
The results of the length-weight relationship analysis in P. segnis indicate that in juveniles and pre-adult crabs, weight gain is almost uniform; males are slightly heavier than females until they attain 10-12 cm carapace width. Thereafter males are heavier than females at any given length . Sukumaran and Neelakantan  found a weight increase was evident above a carapace width of 115 mm in P. pelagicus. The tendency of males to be heavier than females in portunids is in accordance with the observations of Potter et al.  in P. pelagicus and P. sanguinolentus (Herbst, 1783), from Cochin , in P. sanguinolentus from Mangalore of Prasad et al. , in P. sanguinolentus, P. pelagicus, and Scylla serrate from Karwar and of Sukumaran, and of Neelakantan  in P. pelagicus and P. sanguinolentus from Mangalore . However, from the reports of these workers it is understood that there are marked variations in the results of carapace width-weight relationship in portunids from different places, and also within various regions of the same coast.
In contrast to the result and reports of the above workers, found that females of P. pelagicus are heavier than males at a given length. There have been a large number of studies on morphometric in marine crabs along coasts of Persian Gulf [13-15]. Ghorbani et al.  reported that male of P. pelagicus are heavier than female in coasts of Persian Gulf (Boushehr Province), but Jazayeri et al.  found that females of P. pelagicus are heavier than males in coasts of Persian Gulf (khuzestan Province). Tadi et al.  reported that male of P. segnis are heavier than female in coasts of Persian Gulf (Hormozgan Province) . Same studies showed that different size with carapace width ranging from 8 to 15.9 cm for female and 7.8 to 13.7 cm for male and mean weight of males was considerably more than females from Moreton Bay, Eastern Australia [21,22], also Razek  showed that carapace width ranging from 4.5 to 16.5 cm, carapace length from 1.9 to 7 cm for the same species from Bardawil lagoon, Northern Egypt.
In brachyuran crabs chela in males and abdomen in females are considered as secondary sexual characters because of their functions in reproduction. The male crab uses its chela for territorial defense, combat, mating and courtship as well as in carrying and holding the female during copulation. The abdomen in adult females forms an incubation chamber for the developing eggs, which are attached to the setose pleopods. The increase in relative growth of the male chela and female abdomen at the puberty molt brings these structures to full functional size at sexual maturity. Hence the relative growth of chela in males and abdomenin females has been used to determine size at which puberty molt occurs or functional maturity attained.
The result of size at maturity obtained using morphological appearences (male CW50=8.24 cm CW; female CW50=7.44 cm CW) are within the value obtained using relative growth (male=7.5-8.7 cm CW; female=7.1-8.0 cm CW). Thus, this shows that both methods can be used to determine the CW50.
The sex ratio obtained for P. segnis was M: F=0.92:1 (male/female) which showed a significantly more abundant female population. Similar results were reported for Portunus pelagicus, Portunus pelagicus by Jazayeri et al.  and Portunus segnis by Tadi et al. .
We thank Dr. Amir Vazirizadeh and Mr. Ali Mansoori for insightful comments; and for field assistance. Financial support was carried out by Shahid Bheshti University, Iran.
Make the best use of Scientific Research and information from our 700 + peer reviewed, Open Access Journals