Distribution of neuropeptide F in the ventral nerve cord and its possible role on testicular development and germ cell proliferation in the giant freshwater prawn, Macrobrachium rosenbergii.

Neuropeptide F in invertebrates is a homolog of neuropeptide Y in mammals and it is a member of FMRFamide-related peptides. In arthropods, such as insects, there are two types of neuropeptide F comprising long neuropeptide F (NPF) and short neuropeptide F (sNPF). Both NPFs are known to play a crucial role in the regulations of foraging, feeding-related behaviors, circadian rhythm, stress responses, aggression and reproduction in invertebrates. We have earlier found that in the giant freshwater prawn, Macrobrachium rosenbergii, there are three isoforms of NPF and four isoforms of sNPF and that NPFs are expressed in the eyestalks and brain. In the present study, we investigate further the tissue distribution of NPF-I in the ventral nerve cord (VNC) and its role in the development of testes in small male (SM) Macrobrachium rosenbergii. By immunolocalization, using the rabbit polyclonal antibody against NPF-I as a probe, we could detect NPF-I immunoreactivity in the neuropils and neuronal clusters of the subesophageal ganglia (SEG), thoracic ganglia (TG) and abdominal ganglia (AG) of the SM prawns. In functional assays, the administrations of synthetic NPF-I (KPDPTQLAAMADALKYLQELDKYYSQVSRPRFamide) and sNPF (APALRLRFamide) peptides significantly increased the growth rates of SM prawns and significantly increased the gonadosomatic index (GSI) and proliferations of early germ cells in the seminiferous tubules of their testes. It is, therefore, suggestive that NPFs may play critical roles in energy homeostasis towards promoting growth as well as testicular development in prawns that could be applied in the aquaculture of this species.

Characterization and tissue distribution of neuropeptide F in the eyestalk and brain of the male giant freshwater prawn, Macrobrachium rosenbergii.

We previously analyzed the central nervous system (CNS) transcriptome and found three isotypes of long neuropeptide F (MrNPF-I, -II, -III) and four isoforms of short NPF (sMrNPF) in the giant freshwater prawn, Macrobrachium rosenbergii. We now validate the complete sequences of the MrNPF-I and -II precursor proteins, which show high similarity (91-95 %) to NPFs of the penaeus shrimp (PsNPF). MrNPF-I and -II precursors share 71 % amino acid identity, whereas the mature 32-amino-acid MrNPF-I and 69-amino-acid MrNPF-II are identical, except for a 37-amino-acid insert within the middle part of the latter. Both mature MrNPFs are almost identical to PsNPF-I and -II except for four amino acids at the mid-region of the peptides. Reverse transcription plus the polymerase chain reaction revealed that transripts of MrNPF-I and -II were expressed in various parts of CNS including the eyestalk, brain and thoracic and abdominal ganglia, with the highest expression occurring in the brain and thoracic ganglia and with MrNPF-I showing five- to seven-fold higher expression than MrNPF-II. These peptides were also expressed in the midgut hindgut, and hepatopancreas, with MrNPF-I expression in the former two organs being at the same level as that in the brain and thoracic ganglia and about 4-fold higher than NPF-II. The expression of NPFs was also detected in the testes and spermatic duct but appeared much weaker in the latter. Other tissues that also expressed a considerable amount of NPF-I included the hematopoeitic tissue, heart and muscle. By immunohistochemistry, we detected MrNPFs in neurons of clusters 2, 3 and 4 and neuropils ME, MT and SG of the optic ganglia, neurons in cluster 6 and neuropils AMPN, PMPN, PT, PB and CB of the medial protocerebrum, neurons in clusters 9 and 11 and neurophils ON and OGTN of the deutocerebrum and neurons in clusters 14, 15 and 16 and neuropils TN and AnN of the tritocerebrum. Because of their high degree of conservation and strong and wide-spread expression in tissues other than CNS, we believe that, in addition to being a neuromodulator in controlling feeding, MrNPFs also play critical roles in tissue homeostasis. This should be further explored.

Co-culture of males with late premolt to early postmolt female giant freshwater prawns, Macrobrachium rosenbergii resulted in greater abundances of insulin-like androgenic gland hormone and gonad maturation in male prawns as a result of olfactory receptors.

Insulin-like androgenic gland hormone (IAG) controls development of primary and secondary male sex-characteristics in decapod crustaceans. In male giant freshwater prawns, Macrobrachium rosenbergii, the IAG concentration correlates with male reproductive status and aggressiveness. When female prawns are co-cultured with males this can result in male size variations while this variation does not occur when males are cultured in monosex conditions. It was hypothesized that pheromone-like factors from female prawns may affect the abundance of IAG mRNA and protein in co-cultured males which would affect the pattern of sexual maturation of these males. In the present study, late premolt to postmolt females co-cultured with males for 7 days had a greater abundance of MrIAG mRNA transcript in all male phenotypes as well as for the gonad-somatic indexes (GSI). The abundance of MrIAG mRNA gradually increased from days 1 to 7 and using Western blot procedures MrIAG protein also increased in a similar pattern. Furthermore, with use of BrdU labeling, there was an increased cell proliferation in the spermatogenic zone of testicular tubules and in the spermatic duct epithelium during the 1 to 7 day co-culture period when there were increases in MrIAG mRNA and protein. In contrast, these effects were negated if short lateral antennules of males were ablated. Thus, results of the present study provide evidence that there might be female-molting factors which function as important regulators of androgenic gland function and gonadal maturation that were perceived by males via their short lateral antennules which are the olfactory organs.

Starvation Promotes Autophagy-Associated Maturation of the Testis in the Giant Freshwater Prawn, Macrobrachium rosenbergii.

Autophagy is a degradative process of cellular components accomplished through an autophagosomal-lysosomal pathway. It is an evolutionary conserved mechanism present in all eukaryotic cells, and it plays a fundamental role in maintaining tissue homeostasis both in vertebrates and invertebrates. Autophagy accompanies tissue remodeling during organ differentiation. Several autophagy-related genes and proteins show significant upregulations following nutrient shortage (i.e., starvation). In our previous study, we found that in female giant freshwater prawns subjected to a short period of starvation autophagy was up-regulated in consonant with ovarian maturation and oocyte differentiation. Whether and how starvation-induced autophagy impacts on testicular maturation and spermatogenesis of the male prawns remained to be investigated. In this study, we analyzed the effects of starvation on histological and cellular changes in the testis of the giant freshwater prawn Macrobrachium rosenbergii that paralleled the induction of autophagy. Under short starvation condition, the male prawns showed increased gonado-somatic index, increased size, and late stage of maturation of seminiferous tubules, which contained increased number of spermatozoa. Concurrently, the number of autophagy vacuoles and autophagy flux, as monitored by transmission electron microscopy and the autophagic marker LC3, increased in the testicular cells, indicating that a short period of starvation could induce testicular maturation and spermatogenesis in male M. rosenbergii along with modulation of autophagy.

Autophagy-Associated Shrinkage of the Hepatopancreas in Fasting Male Macrobrachium rosenbergii Is Rescued by Neuropeptide F.

Invertebrate neuropeptide F-I (NPF-I), much alike its mammalian homolog neuropeptide Y, influences several physiological processes, including circadian rhythms, cortical excitability, stress response, and food intake behavior. Given the role of autophagy in the metabolic stress response, we investigated the effect of NPF-1 on autophagy during fasting and feeding conditions in the hepatopancreas and muscle tissues of the male giant freshwater prawn Macrobrachium rosenbergii. Starvation up-regulated the expression of the autophagy marker LC3 in both tissues. Yet, based on the relative levels of the autophagosome-associated LC3-II isoform and of its precursor LC3-I, the hepatopancreas was more responsive than the muscle to starvation-induced autophagy. Injection of NPF-I inhibited the autophagosome formation in the hepatopancreas of fasting prawns. Relative to the body weight, the muscle weight was not affected, while that of the hepatopancreas decreased upon starvation and NPF-1 treatment could largely prevent such weight loss. Thus, the hepatopancreas is the reserve organ for the nutrient homeostasis during starvation and NPF-I plays a crucial role in the balancing of energy expenditure and energy intake during starvation by modulating autophagy.