Báo cáo khoa học: Molecular mechanisms regulating molting in a crustacean Halagowder Devaraj and Ayithan Natarajan ppt

indicus only in the early postmolt A and late postmolt B stages but not in the intermolt C, early premolt D0and D1 and late premolt D2-3 sta-ges using antibody to Gas7 Fig.. The 48-kDa

Halagowder Devaraj and Ayithan Natarajan

Unit of Biochemistry, Department of Zoology, University of Madras, Tamil Nadu, India

Periodic shedding of exoskeleton is associated with

growth in crustaceans The mechanisms that control

this phenomenon may also control the growth and

dif-ferentiation processes Eyestalk ablation has been

tra-ditionally carried out to shorten the duration of the

molt cycle and to influence the growth, reproduction

and other metabolic activities of crustaceans [1] Lack

of adequate knowledge on the molecular physiology

of eyestalk ablation, excessive loss of hemolymph,

labor intensiveness, increased incidence of shrimp

mor-tality and reduction in life span restrict the

applicabil-ity of the eyestalk ablation technique to modern

aquaculture practices Efforts therefore have been

made to understand the molecular physiology of

mol-ting and its ramifications in aquaculture practices

As the growth in crustaceans is not continuous

because of the rigid exoskeleton, it is often shed to

allow periodic growth [2] Molting is controlled by

a complex interplay of hormones, in particular, the negative regulation of molt-inhibiting hormone (MIH) from X-organ sinus gland (XO-SG) complex which suppresses the synthesis or secretion of molting hor-mones (ecdysteroids) from the Y-organ [3,4]

As crustacean growth consists of tandem prolifera-tive and growth arrest phases, we investigated the expression of the growth arrest-specific protein (Gas7)

in the molting process of crustaceans Gas7 was pri-marily characterized in NIH 3T3 cultured fibroblast cells which enter a quiescent state following serum deprivation [5] It promotes G0 arrest and is preferen-tially expressed in differentiated neuronal cells and peripheral nerves in mouse and other animals [6] Individual Gas7 genes have been implicated in a vari-ety of biological functions, including the control of

Keywords

crustaceans; ecdysteroid; growth

arrest-specific protein (Gas7); molt-inhibiting

hormone; X-organ sinus gland complex

Correspondence

H Devaraj, Unit of Biochemistry,

Department of Zoology, University of

Madras, Life Sciences Building, Guindy

Campus, Chennai 600 025, Tamil Nadu,

India

Fax: +91 44 22301003

Tel: +91 44 22200574

E-mail: hdrajum@yahoo.com

(Received 20 September 2005, revised

15 December 2005, accepted 22 December

2005)

doi:10.1111/j.1742-4658.2006.05117.x

Crustacean growth and development is characterized by periodic shedding (ecdysis) and replacement of the rigid exoskeleton Secretions of the X-organ sinus gland complex control the cellular events that lead to growth and molting Western blot and ELISA results showed a progressive increase in growth arrest-specific protein (Gas7) from early postmolt stage

to a maximum at late postmolt stage Phosphorylation of ERK2, a down-stream signaling protein, was also identified in the subsequent stages ERK2 phosphorylation resulted in the expression of molt-inhibiting hor-mone (MIH) Specific ERK inhibitors (PD98059 and UO126) exhibited the ability to reduce the molting duration of Fenneropenaeus indicus from 12–14 days to 7–8 days, suggesting that the ERK1⁄ 2 signaling pathway is responsible for the expression of MIH, which controls the molt cycle We have identified the stage-specific expression of Gas7 (
48 kDa) in the X-organ sinus gland complex of eyestalk which is involved in the down-stream signaling of the ERK1⁄ 2 pathway regulating the expression of MIH during the molt cycle of the white shrimp, F indicus These are the first data showing an association between the Gas7 signal-transduction process and regulation of the molt cycle and provides an alternative molecular intervention mechanism to the traditional eyestalk ablation in crustaceans

Abbreviations

ERK, extracellular signal-regulated kinase; Gas7, growth arrest-specific protein 7; MIH, molt-inhibiting hormone; XO-SG complex, X-organ sinus gland complex.

differentiation [7], tyrosine kinase receptor activity [7],

and the negative [8] and positive [7] control of cell

cycling in human Schwann cells

Receptor tyrosine kinases play a central role in

transducing the external signals across cell membranes

into the intracellular signaling systems, which in turn

lead to cell proliferation, differentiation, and other

responses in human Schwann cells [7] Receptor

tyro-sine kinases transduce the signals via extracellular

signal-regulated kinases (ERKs), the serine⁄ threonine

protein kinases belonging to the family of

mitogen-activated protein kinases in cardiac myocytes [9]

ERKs play an important role in the downstream

regu-lation of several cellular processes, such as

prolifer-ation and differentiation, and directly modulate

cellular functions that influence gene transcription and

translation in cancer cells [10]

The role of Gas7 has not been studied so far in

crus-taceans As the XO-SG complex is a structural and

functional homologue of vertebrate hypothalamus,

which is involved in the secretion of neurohormones

that control growth and differentiation processes such

as molting [11], we focused on the expression of Gas7

in the XO-SG complex and its role in the regulation of

MIH expression

Therefore this study aimed to illustrate the

signal-transduction pathway in the regulation of the molt

cycle in Fenneropenaeus indicus and to devise a

mole-cular intervention technology as an alternative to the

traditional eyestalk ablation process

Results

Western blot analysis

Western blot analysis of extracts prepared from the

eyestalk of F indicus during different molting stages

showed a single dominant band of Gas7 only in the

early postmolt (A) and late postmolt (B) stages

(Fig 1A) The immunoreactive band of Gas7 had a

molecular mass of
48 kDa It was prominently

detec-ted in the XO-SG complex using rabbit polyclonal

anti-Gas7 serum, but was not observed in other stages

of molting (Fig 1A)

Immunohistochemical localization

Immunohistochemical analysis of eyestalk neural

gan-glia sections showed a highly positive immunoreactive

expression of Gas7 in the XO-SG complex of the

eye-stalk of F indicus only in the early postmolt (A) and

late postmolt (B) stages but not in the intermolt (C),

early premolt (D0and D1) and late premolt (D2-3) sta-ges using antibody to Gas7 (Fig 2) The immunoreac-tivity of Gas7 was observed prominently as a cluster

of neurosecretory cell bodies or group of cell mass exclusively over the neurosecretory centers of the XO-SG complex Most of the Gas7-expressing neuro-secretory cell bodies were found in the peripheral regions and the neuropile regions of eyestalk neural ganglia and more adjacent to the medulla terminalis X-organ and sinus gland

B

Fig 1 Western blot analysis of proteins from the eyestalk of

F indicus (A) The supernatant from the XO-SG complex of the eyestalk of F indicus was subjected to SDS ⁄ PAGE (10% gel) and electroblotted on to nitrocellulose membrane The
48-kDa Gas7 was detected only in the early postmolt and late postmolt stages

by western blot analysis using rabbit Gas7 polyclonal antibody (B) Protein samples were extracted from the eyestalk of different molting stages of F indicus and subjected to SDS ⁄ PAGE (10% gel); proteins were transferred on to nitrocellulose membrane Phosphorylation of ERK2 protein was found in the intermolt and early premolt stages by a shift in electrophoretic mobility on west-ern blot analysis using rabbit ERK1 ⁄ 2 antibody, goat anti-rabbit IgG–horseradish peroxidase conjugate and developed with 3,3¢-di-aminobenzidine tetrahydrochloride substrate KD, kDa; M, broad range of standard protein markers run on SDS ⁄ 10% polyacryl-amide gel, electroblotted on to nitrocellulose membrane, and stained with Ponceau S red; A, early postmolt; B, late postmolt;

C, intermolt; D0, early premolt; D1, early premolt; D2-3, late premolt.

ELISA Gas7 concentrations were determined by direct ELISA using antibody to Gas7 A progressive increase from the early postmolt stage to a maximum at the late postmolt stage followed by a sudden fall in the sub-sequent stages (Fig 3) was observed The results are consistent with the results of western blot and immu-nohistochemical analysis

Concentrations of the immunoreactively expressed MIH protein were also quantified by direct ELISA from the extracts prepared from the XO-SG complex

of the eyestalk from control groups as well as groups treated with specific inhibitors (PD98059 and UO126)

In control stages, MIH concentrations were increased significantly from early postmolt to a maximum at intermolt, but were dramatically reduced to a mini-mum at early premolt and late premolt stages In the case of the PD98059-treated and UO126-treated stages (intermolt and early premolt), MIH concentrations were reduced to a basal level (Fig 4A,B)

Phosphorylation of ERK2 Phosphorylation or activation of ERK2 protein was found only in intermolt and early premolt by a shift

in mobility on western blot analysis (Fig 1B) No shift in electrophoretic mobility was observed in early postmolt, late postmolt, early premolt and late premolt stages

Fig 2 Immunohistochemical localization of Gas7 expression was

observed only in (A) early postmolt and (B) late postmolt stages in

the eyestalk tissue of F indicus using rabbit polyclonal antibody to

Gas7 (N), Negative control treated with normal goat serum not

showing expression of Gas7; ME, medulla externa; MI, medulla

interna; MT, medulla terminalis; SG, sinus gland; XO, X-organ; NSC,

neurosecretory cell bodies Scale bar represents 100 lm.

Fig 3 Quantitative determination of Gas7 concentrations in extracts prepared from the XO-SG complex of F indicus by direct ELISA using rabbit polyclonal antibody to Gas7 The line diagram represents high concentrations of Gas7 immunoreactivity only in early postmolt, maximum at late postmolt, and basal level in subse-quent stages Values are expressed as mean ± SD (n ¼ 5).

Treatment with inhibitors and blocking

of ERK2 activation

Phosphorylation of ERK2 and expression of MIH were

studied in both control and inhibitor-treated (PD98059

and UO126) stages Phosphorylation of ERK2 was

detected as a shift in mobility during the intermolt

and early premolt stages of control shrimps, whereas

PD98059-treated stages (intermolt and early premolt)

showed no shift in ERK2 protein mobility using rabbit

anti-ERK1⁄ 2 IgG (Fig 5A) Mouse

anti-phospho-ERK1⁄ 2 IgG specifically detected only phosphorylated

ERK2 protein in control groups of intermolt and early

premolt stages, but the antibody could not detect the

ERK2 protein in UO126-treated stages (Fig 5B) Like-wise, the immunoreactive band of MIH was also detec-ted only in the control stages, i.e early postmolt, late postmolt, intermolt and early premolt, but not in the PD98059-treated and UO126-treated stages (intermolt and early premolt) (Fig 6A,B) The results are consis-tent with the results of direct ELISA

Fig 4 Effect of (A) PD98059 and (B) UO126 on MIH

concentra-tions of F indicus MIH concentraconcentra-tions were determined by direct

ELISA in extracts prepared from control (Untreated) and PD98059

or UO126 treated stages of F indicus using anti-r-Pej-MIH IgG.

The bar diagram shows the highly significant concentrations

(P < 0.0001; analysis of variance) of MIH in the intermolt stage of

the control samples, but PD98059 and UO126 treated stages

(inter-molt and early pre(inter-molt) show very low concentrations of MIH.

Values are expressed as mean ± SD (n ¼ 5).

B

Fig 5 Effect of (A) PD98059 and (B) UO126 on the phosphoryla-tion of the ERK2 protein from the XO-SG complex (A) Protein sam-ples from the XO-SG complex of different molting stages were run

on SDS ⁄ 10% polyacrylamide gel and electroblotted on to nitrocellu-lose membrane Phosphorylation of the ERK2 protein was detected

by a shift in electrophoretic mobility on western blot analysis only

in control stages (intermolt and early premolt), but PD98059-treated stages did not show ERK2 phosphorylation using rabbit antibody to ERK1 ⁄ 2 (B) Mouse anti-phosphoERK1 ⁄ 2 IgG specifically detected only phosphorylated ERK2 protein in control groups of intermolt and early premolt stages, but the antibody could not detect the ERK2 protein in UO126-treated stages KD, kDa; M, broad range

of standard protein markers run on SDS ⁄ 10% polyacrylamide gel, electroblotted on to nitrocellulose membrane, and stained with Ponceau S red; A, early postmolt; B, late postmolt; C, intermolt;

D 0 , early premolt; D 1 , early premolt; D 2-3 , late premolt.

Molting duration of F indicus

The inhibitor-treated (PD98059 and UO126) stages

showed an absence of MIH, which reduces the molting

duration of F indicus The shrimps in the control

groups required
12–14 days to complete the molt

cycle, whereas in those injected with either PD98059 or

UO126 the duration of the molt cycle was reduced to

7–8 days (Fig 7) The available data also show a

correlative and significant change in the shortening of

the molt cycle which leads to frequent molting and

growth of shrimps

Discussion

Gas7 is a multifunctional protein involved in the mat-uration of neurons and release of neurotransmitters [5] The stage-specific expression of the Gas7 gene using RT-PCR of Gas7 mRNA and coimmunoprecipi-tation of Sky receptor has been identified in the early and late postmolt stages of Penaeus monodon, suggest-ing that Gas7 may act as a ligand for tyrosine kinase Sky receptor (unpublished work) ERK2 is part of the Ras⁄ Raf ⁄ MEK downstream signaling pathway for many growth factors that act by binding to tyrosine kinase receptors in cardiac myocytes [19] The mito-gen-activated protein kinase pathway is involved in a number of cellular changes inducing growth and differ-entiation in human Schwann cells [7] In cardiac myo-cytes, protein kinase C generates a positive feedback loop to ERK2 phosphorylation [19], and this effect has also been demonstrated in P monodon (unpub-lished work)

In decapod crustaceans, the growth and differenti-ation processes are controlled by a complex interplay

of neuropeptides that are stage specific and inducible [3,4] To elucidate the functional necessity of Gas7

in MIH expression, highly selective ERK inhibitors (PD98059 and UO126) were used, which completely inhibited the Gas7-dependent downstream signaling during ERK2 phosphorylation ERK2 is active only when it is phosphorylated [7] Inhibition of ERK2 with ERK⁄ MEK inhibitors (PD98059 and UO126) appears

A

B

Fig 6 Effect of (A) PD98059 and (B) UO126 on
7–8-kDa MIH

from the XO-SG complex Protein samples prepared from the

XO-SG complex of the eyestalk of F indicus were run on

SDS ⁄ 15% polyacrylamide gel Immunoblotting was performed

using anti-r-Pej-MIH IgG in different molting stages The
7–8-kDa

MIH protein was detected only in the control stages (early

post-molt, late postpost-molt, intermolt and early premolt), whereas shrimps

treated with PD98059 and UO126 (intermolt and early premolt

sta-ges) show an absence of MIH immunoreactivity KD, kDa; M, broad

range of standard protein markers run on SDS ⁄ 15% polyacrylamide

gel, electroblotted on to nitrocellulose membrane, and stained with

Ponceau S red; A, early postmolt; B, late postmolt; C, intermolt;

D 0 , early premolt; D 1 , early premolt; D 2-3 , late premolt.

Fig 7 Molt cycle duration of F indicus in controls and shrimps injected with specific inhibitors (PD98059 and UO126) on day 3 after the first molt was recorded as hours between the first molt and the second molt Values are mean ± SD (n ¼ 5) The highly significant (P < 0.0001, analysis of variance) reduction in molt cycle duration was observed only in the D1stage.

shift in the mobility of ERK2 protein during

inter-molt and early preinter-molt stages, resulting in the

down-regulation of MIH expression The data show that

phosphorylation of ERK2 results in activation of

tran-scription factors inside the nucleus that modulate MIH

gene transcription and translation

The shrimps treated with ERK inhibitors showed a

shortening of the intermolt and early premolt periods,

which suggests changes in the periodicity of the

mol-ting process In addition, the molt cycle duration of

F indicus was reduced dramatically from 12 ± 2 days

to 7 ± 1 days when the shrimps were injected with

ERK inhibitors Thus, application of these inhibitors

significantly reduced the molt cycle duration, as they

inhibit MIH by interfering with downstream signals

from Gas7 Hence, these data clearly indicate that

transcription of Gas7 occurs through co-ordinated

events involving activation of the ERK signal (Fig 8)

These are the first data to show an association

between the Gas7 gene and molting processes in

crus-taceans mediated by the expression of MIH through

the ERK1⁄ 2 signaling pathway Reduction of the molt

cycle by ERK inhibitors has an application potential

in the aquaculture industry

Experimental animals The Indian white shrimp F indicus was selected for this study because of its nonseasonal availability and easy main-tenance They were obtained from the coastal region of Kovalam, Chennai, India They were maintained in the laboratory at a temperature of 28 ± 2
C under natural photoperiod (12 h light⁄ 12 h darkness) in plastic tanks con-taining filtered, continuously aerated seawater (26–28% salinity) The stocking density was 10 shrimps per tank in accordance with the water quality The filtered seawater was changed everyday, and the animals were fed every day

ad libitumwith commercial feed pellets

Identification of molting stages The different molting stages of F indicus were determined from morphological changes in the setae of the uropod and pleopod, carapace and exoskeleton, on the basis of criteria established by Vijayan et al [12] The pleopod and uropod

of the same animal were removed and placed on a clean micro slide; the slide was then covered with a rectangular coverslip The slide was kept under a light microscope and the various molting stages such as early postmolt (A), late

Gas7 Gas7 binding to Sky receptor

(Stage A and B)

PD98059 UO126

Inhibition of ERK2 Phosphorylation (Stage C and D 0 )

Inhibition of MIH expression (Stage C and D 0 )

Phosphorylation of ERK2

(Stage C and D 0 )

P P

Ras

Raf

MEK1

ERK1/2

MIH

Expression of MIH

(Stage C and D

0 )

Sky receptor phosphorylation (Stage B and C)

Fig 8 Role of Gas7 in the molt cycle of

F indicus Sky receptor dimerization and autophosphorylation is mediated by Gas7 during early postmolt (A) and late postmolt (B) stages Activation of the Ras ⁄ Raf ⁄ MEK pathway subsequent to Sky receptor activa-tion results in ERK2 phosphorylaactiva-tion and expression of MIH during intermolt (C) and early premolt (D0) which suppresses the ecdysteroid concentrations Inhibition of ERK2 phosphorylation by PD98059 and UO126 suppresses MIH expression and increases ecdysteroid concentrations, which results in shortening of the molt cycle.

postmolt (B), intermolt (C), early premolt (Doand D1) and

late premolt (D2-3) were identified

Extraction of eyestalk neural ganglia

The eyestalks were clipped from different molting stages of

live shrimps The eyestalks containing whole peduncular

neural ganglia (XO-SG complex) were dissected from the

surrounding exoskeleton of the eyestalk under a Carl Zeiss

(Go¨ttingen, Germany) Stereo Zoom dissection microscope

They were homogenized in lysis buffer containing 135 mm

NaCl, 20 mm Tris⁄ HCl, 2 mm EDTA and 1 mm

phenyl-methanesulfonyl fluoride, pH 7.4, as described by Watson

et al.[13], with slight modifications The total homogenate

was microfuged at 8000 g, 4
C for 10 min, and the

super-natant was recovered in different eppendorf tubes They

were stored at)20
C until subsequent analysis.

Western blot analysis

The proteins were separated by SDS⁄ PAGE (10% gel) for

the detection of Gas7 [14] and electroblotted [15] on a

nitrocellulose membrane at 25 V⁄ 130mA for 4 h at 4
C

The membrane was incubated overnight at 4
C with rabbit

polyclonal antibody to Gas7 (1 : 1000 dilution; gift from S

Lin-Chao, Institute of Molecular Biology, Academia Sinica,

Taiwan) followed by incubation for 2 h at room

tempera-ture with goat anti-rabbit IgG (1 : 2000 dilution)

conju-gated with horseradish peroxidase Finally, Gas7 was

detected by incubation with 3,3¢-diaminobenzidine

tetra-hydrochloride as chromogenic substrate by the method

of Ju et al [5]

Immunohistochemistry

Paraffin sections (15 lm) were prepared by conventional

methods [16] The tissue sections were dewaxed in xylene and

rehydrated in descending alcohol series and washed in

NaCl⁄ Pi(pH 7.4) After being blocked with 3% BSA⁄ Tris ⁄

NaCl⁄ Tween, the sections were incubated separately with

Gas7 antibody (1 : 1000 dilution) for 16–18 h at 4
C After

being washed, goat anti-rabbit IgG–horseradish conjugate

(1 : 2000 dilutions) was applied to the sections for 2 h at

room temperature Subsequently, Tris⁄ NaCl (pH 7.6)

con-taining 0.05% 3,3¢-diaminobenzidine tetrahydrochloride and

0.01% H2O2were added as substrate for color development

The reaction was stopped with Tris⁄ NaCl, dehydrated in an

ascending alcohol series, cleared in xylene, and mounted with

DPX permount for observation [17]

ELISA

ELISA was performed to analyze the concentrations

of Gas7 present in the eyestalk as well as to study the

concentrations of MIH in the presence of inhibitors (PD98059 and UO126) in the different stages of F indicus as described by Shih et al [17] In this assay, the specific pro-tein samples were diluted with coating buffer and coated on

to 96-well microtiter plates The primary antiserum used was anti-Gas7 (1 : 1000 dilution) Goat anti-rabbit IgG–horse-radish peroxidase conjugate (1 : 2000 dilution) was used as secondary antibody Thereafter, 3,3¢,5,5¢-tetramethylbenzi-dine was used for color development The reaction was stopped with 1 m H2SO4, and the absorbance of the protein was measured spectrophotometrically at 450 nm

Phosphorylation of ERK2 Phosphorylation of ERK2 was detected by a shift in elec-trophoretic mobility as described by Li et al [7] The protein samples of different molting stages of F indicus were run on SDS⁄ 10% polyacrylamide gels and transferred to nitrocellu-lose membrane (25 V, 130mA for 4 h) The membrane was treated with antibodies raised in rabbit against ERK1⁄ 2 pro-tein (primary antibody, 1 : 1000 dilution; Chemicon Inter-national, Temecula, CA, USA) followed by incubation with goat anti-rabbit IgG (1 : 2000 dilution) coupled with horse-radish peroxidase The membrane was later incubated with 3,3¢-diaminobenzidine tetrahydrochloride substrate

Treatment with inhibitors (PD98059 and UO126) and blocking of ERK2 activation

The cultivable white shrimps (F indicus) were purchased, and two groups of animals at different molting stages were maintained in the laboratory (salinity 26–28%, pH 8.1, and temperature 28 ± 2
C) Each group contained 10–15 shrimps, of which, one group from the intermolt and early premolt stages were injected with specific inhibitors, and the other served as control PD98059 and UO126 (Chem-icon International) are highly selective in vivo inhibitors of the ERK kinase cascade A 50 lm solution was diluted in dimethyl sulfoxide and injected into test shrimps via the arthrodial joints The control groups were injected with dimethyl sulfoxide only [18]

The injected shrimps were maintained until they reached the second molt of the same stage Then, the neural ganglia were dissected and homogenized in lysis buffer on ice The supernatant was recovered after centrifugation at

10 000 r.p.m for 10 min The extracts prepared from the XO-SG complex of inhibitor-injected and control shrimps were run on SDS⁄ 10% polyacrylamide gel and electroblot-ted on to nitrocellulose membrane Then, the membranes were probed separately with rabbit anti-ERK1⁄ 2, mouse anti-phosphoERK1⁄ 2 and anti-r-Pej-MIH IgG In addition, the molting behaviors and molting duration were observed

in the control and inhibitor-treated shrimps, and the data were recorded

Statistical analysis

Mean and standard deviation were calculated Differences

between molting stages were analyzed using one-way

analy-sis of variance on spss version 10.0 software (SPSS Inc.,

Chicago, IL, USA)

Acknowledgements

This work was supported by grants from the

Depart-ment of Science and Technology (DST), UGC-DRS

program, COSIST program and Department of

Bio-technology (DBT) (BT PR3992⁄ AA2 ⁄ 03 ⁄ 202 ⁄ 2003),

New Delhi We gratefully acknowledge Dr Sue

Lin-Chao, Institute of Molecular Biology, Academia Sinica,

Taiwan, for the gift of Gas7 antibody and Dr Tsuyoshi

Ohira, Department of Applied Biological Chemistry,

University of Tokyo, Japan, for the gift of MIH

anti-body We also acknowledge Mr A Anand Kumar for

his help in the preparation of the manuscript

References

1 Chang ES (1995) Physiological and biochemical changes

during the molt cycle in decapod crustaceans: an

over-view J Exp Mar Biol Ecol 193, 1–14

2 Keller R (1992) Crustacean neuropeptides: structures,

function and comparative aspects Experientia 48, 439–

447

3 Soumoff C & O’Connor JD (1982) Repression of

Y-organ secretory activity by molt-inhibiting hormone

in the crab, Pachygrapsus crassipes Gen Comp

Endocri-nol 48, 432–439

4 Mattson MP & Spaziani E (1985) Characterization of

molt-inhibiting hormone (MIH) action on crustacean

Y-organ segments and dispersed cells in culture and a

bioassay for MIH activity J Exp Zool 236, 93–101

5 Ju YT, Chang ACY, She BR, Tsaur ML, Hwang HM,

Chao CCK, Cohen SN & Lin-Chao S (1998) gas7: a

gene expressed preferentially in growth-arrested

fibro-blasts and terminally differentiated Purkinje neurons

affects neurite formation Proc Natl Acad Sci USA 95,

11423–11428

6 Brancolini C, Bottega S & Schneider C (1992) Gas 2, a

growth arrest-specific protein, is a component of the

microfilament network system J Cell Biol 117, 1251–

1261

7 Li R, Chen J, Hammonds G, Phillips H, Armanini M,

Wood P, Bunge R, Godowski PJ, Sliwkowski MX &

Mather JP (1996) Identification of gas6 as a growth factor

for human Schwann cells J Neuro Sci 16, 2012–2019

8 Del Sal G, Collavin L, Ruaro ME, Saccone S, Della

Valle G & Schneider C (1994) Structure, function, and

homologue of the murine gas1 genes Proc Natl Acad Sci USA 91, 1848–1852

9 Bogoyevitch MA, Glennon PE, Andersson MB, Clerk

A, Lazou A, Marshall CJ, Parker P & Sugden PH (1994) Endothelin-1 and fibroblast growth factors sti-mulate the mitogen-activated protein kinase signaling cascade in cardiac myocytes J Biol Chem 269, 1110– 1119

10 Osborn MT & Chambers TC (1996) Role of stress-acti-vated⁄ c-Jun NH2-terminal protein kinase pathway in the cellular response to adriamycin and other chemo-therapeutic drugs J Biol Chem 271, 30950–30955

11 Cooke IM & Sullivan RE (1982) Hormones and neuro-secretion In The Biology of Crustacea: Structure and Function(Atwood HL & Sandeman DC, eds), vol 3, pp 205–290 Academic Press, New York

12 Vijayan KK, Sunil Kumar MK & Diwan AD (1997) Studies on molt staging, molting duration and molting behavior in Indian white shrimp, Penaeus indicus Milne Edwards (Decapoda: Penaeidae) J Aqua Trop 12, 53–64

13 Watson RD, Lee KJ, Borders KJ, Dircksen H & Lilly

KY (2001) Molt-inhibiting hormone immunoreactive neurons in the eyestalk neuroendocrine system of the blue crab, Callinectes sapidus Arthropd Struct Dev 30, 69–76

14 Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4 Nature 227, 680–686

15 Towbin H, Staehelin T & Gordon J (1979) Electro-phoretic transfer of proteins from polyacrylamide gel to nitrocellulose sheets Procedure and some applications Proc Natl Acad Sci USA 76, 4350–4354

16 Presnell JK & Screibman MP (1997) Humason’s Animal Tissue Techniques.Johns Hopkins University Press, Baltimore

17 Shih TW, Suzuki Y, Nagasawa H & Aida K (1998) Immunohistochemical identification of hyperglycemic hormone and molt-inhibiting hormone-producing cells

in the eyestalk of the kuruma prawn, Penaeus japonicus Zool Sci 15, 389–397

18 Strohm C, Barancik T, Bruhl ML, Kilian SA & Schaper

W (2000) Inhibition of the ER Kinase cascade by PD98059 and UO126 counteracts ischemic precondition-ing in pig myocardium J Cardiovasc Pharmacol 36, 218–229

19 Kometiani P, Li J, Gnudi L, Kahn BB, Askari A & Xie

Z (1998) Multiple signal transduction pathways link

Na+⁄ K+-ATPase to growth-related genes in cardiac myocytes The role of Ras and mitogen-activated pro-tein kinases J Biol Chem 273, 15249–15256