Molt cycle-dependent molecular chaperone and polyubiquitin gene expression in lobster

Lobster claw muscle undergoes atrophy in correlation with increasing ecdysteroid (steroid molting hormone) titers during premolt. In vivo molecular chaperone (constitutive heat shock protein 70 [Hsc70], heat shock protein 70 [Hsp70], and Hsp90) and polyubiquitin messenger ribonucleic acid (mRNA) levels were examined in claw and abdominal muscles from individual premolt or intermolt lobsters. Polyubiquitin gene expression was assayed as a marker for muscle atrophy. Both Hsc70 and Hsp90 mRNA levels were significantly induced in premolt relative to intermolt lobster claw muscle, whereas Hsp70 mRNA levels were not. Hsp90 gene expression was significantly higher in premolt claw muscle when compared with abdominal muscle. Polyubiquitin mRNA levels were elevated in premolt when compared with intermolt claw muscle and significantly elevated relative to premolt abdominal muscle.     

Eyestalk ablation has little effect on actin and myosin heavy chain gene expression in adult lobster skeletal muscles

The organization of skeletal muscles in decapod crustaceans is significantly altered during molting and development. Prior to molting, the claw muscles atrophy dramatically, facilitating their removal from the base of the claw. During development, lobster claw muscles exhibit fiber switching over several molt cycles. Such processes may be influenced by the secretion of steroid molting hormones, known collectively as ecdysteroids. To assay the effects of these hormones, we used eyestalk ablation to trigger an elevation of circulating ecdysteroids and then quantified myofibrillar mRNA levels with real-time PCR and myofibrillar protein levels by SDS-PAGE. Levels of myosin heavy chain (MHC) and actin proteins and the mRNA encoding them were largely unaffected by eyestalk ablation, but in muscles from intact animals, myofibrillar gene expression was modestly elevated in premolt and postmolt animals. In contrast, polyubiquitin mRNA was significantly elevated (about 2-fold) in claw muscles from eyestalk-ablated animals with elevated circulating ecdysteroids. Moreover, patterns of MHC and actin gene expression are significantly different among slow and fast claw muscles. Consistent with these patterns, the three muscle types differed in the relative amounts of myosin heavy chain and actin proteins. All three muscles also co-expressed fast and slow myosin isoforms, even in fibers that are generally regarded as exclusively fast or slow. These results are consistent with other recent data demonstrating co-expression of myosin isoforms in lobster muscles.     

Myofibrillar gene expression in differentiating lobster claw muscles

Lobster claw muscles undergo a process of fiber switching during development, where isomorphic muscles containing a mixture of both fast and slow fibers, become specialized into predominantly fast, or exclusively slow, muscles. Although this process has been described using histochemical methods, we lack an understanding of the shifts in gene expression that take place. In this study, we used several complementary techniques to follow changes in the expression of a number of myofibrillar genes in differentiating juvenile lobster claw muscles. RNA probes complementary to fast and slow myosin heavy chain (MHC) mRNA were used to label sections of 7th stage (approximately 3 months old) juvenile claw muscles from different stages of the molt cycle. Recently molted animals (1-5 days postmolt) had muscles with distinct regions of fast and slow gene expression, whereas muscles from later in the molt cycle (7-37 days postmolt) had regions of fast and slow MHC expression that were co-mingled and indistinct. Real-time PCR was used to quantify several myofibrillar genes in 9th and 10th stages (approximately 6 months old) juvenile claws and showed that these genes were expressed at significantly higher levels in the postmolt claws, as compared with the intermolt and premolt claws. Finally, Western blot analyses of muscle fibers from juvenile lobsters approximately 3 to 30 months in age showed a shift in troponin-I (TnI) isoform expression as the fibers differentiated into the adult phenotypes, with expression of the adult fast fiber TnI pattern lagging behind the adult slow fiber TnI pattern. Collectively, these data show that juvenile and adult fibers differ both qualitatively and quantitative in the expression of myofibrillar proteins and it may take as much as 2 years for juvenile fibers to achieve the adult phenotype.     

Burn-induced increase in atrogin-1 and MuRF-1 in skeletal muscle is glucocorticoid independent but downregulated by IGF-I

The present study determined whether thermal injury increases the expression of the ubiquitin (Ub) E3 ligases referred to as muscle ring finger (MuRF)-1 and muscle atrophy F-box (MAFbx; aka atrogin-1), which are muscle specific and responsible for the increased protein breakdown observed in other catabolic conditions. After 48 h of burn injury (40% total body surface area full-thickness scald burn) gastrocnemius weight was reduced, and this change was associated with an increased mRNA abundance for atrogin-1 and MuRF-1 (3.1- to 8-fold, respectively). Similarly, burn increased polyUb mRNA content in the gastrocnemius twofold. In contrast, there was no burn-induced atrophy of the soleus and no significant change in atrogin-1, MuRF-1, or polyUb mRNA. Burns also did not alter E3 ligase expression in heart. Four hours after administration of the anabolic agent insulin-like growth factor (IGF)-I to burned rats, the mRNA content of atrogin-1 and polyUb in gastrocnemius had returned to control values and the elevation in MuRF-1 was reduced 50%. In contrast, leucine did not alter E3 ligase expression. In a separate study, in vivo administration of the proteasome inhibitor Velcade prevented burn-induced loss of muscle mass determined at 48 h. Finally, administration of the glucocorticoid receptor antagonist RU-486 did not prevent burn-induced atrophy of the gastrocnemius or the associated elevation in atrogin-1, MuRF-1, or polyUb. In summary, the acute muscle wasting accompanying thermal injury is associated with a glucocorticoid-independent increase in the expression of several Ub E3 ligases that can be downregulated by IGF-I.     

Contractile proteins of fast and slow fibers during differentiation of lobster claw muscle

Contractile protein populations were determined, using gel electrophoresis, during development of the claw closer muscles of the lobster Homarus americanus. In the adult the paired claw closer muscles are asymmetric, consisting of a crusher muscle with all slow fibers and a cutter muscle with a majority of fast and a few slow fibers. The electrophoretic banding pattern of these adult fast and slow fibers shows a similarity in the major proteins including myosin, actin, and tropomyosin which are common to both fiber types. Paramyosin is slightly heavier in fast fibers than in slow. However, fast fibers have three proteins and slow fibers have four proteins which are unique to themselves. Several of these unique proteins belong to the regulatory troponin complexes. In juvenile 4th stage lobster, where the paired closer muscles are undifferentiated, the banding pattern reveals the presence of proteins common to both fiber types including myosin, actin, and tropomysin but the conspicuous absence of all unique fast fiber proteins as well as one unique slow fiber protein. By the juvenile 10th stage most of these unique proteins are present except for one unique slow fiber protein. Thus lobster fast and slow fiber differentiation entails coordinate gene activation to add unique contractile proteins.     

Muscle Restructuring in Crustaceans: Myofiber Death, Transfiguration and Rebirth

Research on the dimorphic claws of the snapping shrimp Alpheushas revealed moult-associated changes in structure and biochemicalcomposition—including atrophy and biochemical modification—ofclaw muscle fibers during morphological transformation of aclaw from a pincer to a snapper. Electrophysiology, SDS-PAGEgel electrophoresis, and immunocytochemistry were used to analyzechanges in claw closer muscle function and composition duringthe transformation process. Remodification of closer muscleduring claw transformation, involving the complete loss of acentral section of fast-contracting fibers and their replacementthrough enlargement of existing slowly-contracting segmentsof the muscle, may mimic similar muscle modifications duringinitial claw development. Exposure of intact animals to environmentalecdysteroid hormones accelerated the rate of these changes.These processes appear to be a product of a remarkable trophicplasticity of crustacean skeletal muscle first discovered bySkinner.     

Identification of a transforming growth factor-β type I receptor transcript in Eriocheir sinensis and its molting-related expression in muscle tissues

The transforming growth factor-β (TGF-β) signaling pathway is conserved across animals, and knowledge of its roles during the molt cycle in crustaceans is presently very limited. This study investigates the roles of the TGF-β receptor in molting-related muscle growth in Eriocheir sinensis. Using the RT-PCR and RACE techniques, we obtained a 1722 bp cDNA sequence encoding a transforming growth factor-β type I receptor in Eriocheir sinensis, designated EsTGFBRI, which contains a 124 bp 5′-untranslated region, a 20 bp partial 3′-untranslated region and a 1578 bp open reading frame encoding 525 amino acids. The deduced EsTGFBRI contains an N-terminal 24 amino acid signal peptide, an activin type I and II receptor domain, a transmembrane helix region, a glycine-serine-rich motif, and a conserved serine/threonine kinase catalytic domain including an activation loop. The qRT-PCR results showed that EsTGFBRI gene was highly expressed in the intermolt testis and ovary in mature crabs. In juvenile crabs, the mRNA levels of EsTGFBRI in claw and abdominal muscles in the later premolt D_3–4 stage were significantly higher than those in the intermolt C and postmolt A–B stages. There was no significant change in EsTGFBRI mRNA levels in walking leg muscles during the molt cycle. The results suggest that EsTGFBRI is probably play roles in molting-related muscle growth in E. sinensis. This study provides a necessary basis for elucidating the functions of TGF-β-like signaling mediated by TGFBRI in molting-related muscle growth in crustaceans.

     

Molting cycle-dependent expression of CYP4C15, a cytochrome P450 enzyme putatively involved in ecdysteroidogenesis in the crayfish, Orconectes limosus.

A cytochrome P450 enzyme cDNA (CYP4C15) has been previously cloned from a cDNA library of crayfish steroidogenic glands (Y-organs). The conceptual translation of the CYP4C15 cDNA sequence was analyzed for regions of putative high antigenicity and a mixture of two synthetic peptides was chosen for the production of a specific polyclonal antibody. Western blot analysis on Y-organ subcellular fractions indicated an endoplasmic reticulum location of CYP4C15, in agreement with the structural feature of the predicted protein, i.e. the presence of a hydrophobic N-terminal segment.The protein is only expressed in Y-organs, thus showing a similar distribution to the corresponding mRNA. From this tissue specific expression, it has been postulated that CYP4C15 would play a role in ecdysteroid biosynthesis rather than detoxification and the variations of its expression during a molt cycle were carefully examined. CYP4C15 is not detectable in intermolt animals, expression levels are maximal during early premolt and decrease during late premolt. The results are discussed in relation to the variations of hemolymphatic ecdysteroid titers and steroidogenic capacities of the Y-organs during the molt cycle.     

Getting out of a Tight Squeeze--Enzymatic Regulation of Claw Muscle Atrophy in Molting

The claw closer muscle of the land crab, Gecarcinus lateralis,undergoes a cyclical atrophy and restoration during the intervalbetween ecdyses. During proecdysis (stage D₀), 30–60%of the muscle protein is degraded, which reduces tissue massand facilitates withdrawal of the propodus at ecdysis. Proteinis resynthesized as the muscle grows back to its previous sizeduring metecdysis. This atrophy is specific to the claws andcan be accentuated by multiple limb autotomy. Crustacean musclescontain five cytosolic proteinases that degrade myofibrillarproteins. Four of these constitute a family of enzymes requiringCa²⁺ for activity. These calcium-dependent proteinases (CDPs)hydrolyze myofibrillar proteins in vitro and in situ and showincreased activity in atrophic claw muscles, which suggeststhat CDPs play an important role in myofibrillar protein metabolism.The fifth enzyme is a multicatalytic proteinase (MCP), a multisubunitproteolytic complex that degrades a wide range of peptide andprotein substrates. The catalytic properties of the complexare altered with low concentrations of sodium dodecyl sulfateor by brief heating at 60°C. Only the heat-activated formdegrades myofibrillar proteins. Since the CDPs hydrolyze contractileproteins about 30-fold more rapidly than the heat-activatedMCP, the MCP probably has a more limited or specialized functionin molt-induced claw muscle atrophy.     

Histochemical and biochemical characterization of two slow fiber types in decapod crustacean muscles

Myofibrillar proteins in muscles of the claws and abdomen of lobster, Homarus americanus, and the claws of fiddler crab, Uca pugnax, and land crab, Gecarcinus lateralis, have been analyzed with sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Fibers contained numerous isoforms of structural and regulatory proteins in assemblages correlated with fiber type. One fast (F) and two slow (S1 and S2) fibers were identified. All F fibers possessed two isoforms of paramyosin (P1 and P2), while all slow fibers, with the exception of Uca major claw, contained only the P2 variant. S1 and S2 fibers were distinguished by the distribution of a large isoform of troponin-T (T1; Mr = 55,000); S2 fibers in all three species contained T1 in addition to one or two smaller-molecular-weight variants usually associated with S1 fibers. In order to determine whether the slow fibers differed in histochemical properties, land crab claw closer muscle was cryosectioned and stained for myofibrillar ATPase and NADH diaphorase activities. Most S2 fibers had lower ATPase and higher NADH diaphorase activities than S1 fibers, which indicated that S2 fibers had a lower rate of contraction and were more fatigue-resistant than S1 fibers. It is proposed that the S1 and S2 fibers defined by biochemical and histochemical criteria are identical to the slow-twitch and tonic fibers, respectively characterized physiologically.     

Ca2+-Activated Force Production and Calcium Handling by the Sarcoplasmic Reticulum of Crustacean Muscles During Molt-Induced Atrophy

Growth in crustaceans is an intermittent process centered aroundthe principal event of ecdysis. A major problem facing decapodcrustaceans at the time of ecdysis is the withdrawal of thelarge muscle mass of the chelae through the narrow basi-ischialjoints. To overcome this problem the muscle undergoes an atrophytriggered by the molt, which reduces the muscle mass. Once theanimal is freed from the old exoskeleton, the muscle fibers,must elongate to accommodate the new larger exoskeleton. Despitethis major myofibrillar remodification, the muscles are thoughtto remain functional over the molt cycle. Studies using skinnedmuscle fibers have shown that long-sarcomere fibers maintaintheir function over the molt cycle while the contractile propertiesof the short-sarcomere fibers are modified, as fibers couldnot withstand maximal activation with Ca²⁺ during the premoltstage. In this study the maximum Ca²⁺-activated force productionand the ability of the sarcoplasmic reticulum (SR) to releaseaccumulated Ca²⁺ has been investigated in the two major fibertypes in the claw muscle of Cherax destructor, in the stagesjust prior to ecdysis and during inter molt. In both long- andshort-sarcomere fibers, the amount of Ca²⁺ released by the SRwas not different in premolt and intermolt stages. However,the maximum releasing capacity of the SR was reached in a shortertime during the premolt suggesting that Ca²⁺ is being accumulatedat a faster rate. The force production was greatly reduced andwas graded during the premolt in both fiber types. This modulationof force appears to be the most likely candidate regulatingthe magnitude of the force development in the periods when fibersare undergoing myofibrillar remodification and thus may serveto prevent fiber damage.     

A ubiquitin C-terminal isopeptidase that acts on polyubiquitin chains. Role in protein degradation.

In the ubiquitin (Ub) pathway, proteins are ligated with polyUb chains and then are degraded by a 26 S protease complex. We describe an enzyme, called isopeptidase T, that acts on polyUb chains. It is a monomeric Ub-binding protein abundant in erythrocytes and reticulocytes. The activity of the isopeptidase is inhibited by iodoacetamide and Ub aldehyde. Treatment of the enzyme with Ub aldehyde increased its affinity for free Ub, indicating the existence of two different Ub-binding sites and cooperativity between the two sites. Isopeptidase T acts on polyUb-protein conjugates, but not on conjugates in which the formation of polyUb chains was prevented by the use of reductively methylated Ub or on abnormal polyUb chains formed with a mutant Ub that contains a Lys----Arg substitution at residue 48. The enzyme converts high molecular mass polyUb-protein conjugates to lower molecular mass forms with the release of free Ub, but not of free protein substrate. The lower molecular mass Ub-protein conjugate products are resistant to further action of the enzyme. Isopeptidase T stimulates protein degradation in a system reconstituted from purified enzyme components. The enzyme also stimulates the degradation of proteins ligated to polyUb chains by the 26 S protease complex. Preincubation of polyUb-protein conjugates with the isopeptidase did not much increase their susceptibility to proteolysis by the 26 S complex. On the other hand, preincubation of conjugates with the 26 S protease complex and ATP increased the release of free Ub upon further incubation with the isopeptidase. It thus seems that a role of this isopeptidase in protein breakdown is to remove polyUb chain remnants following the degradation of the protein substrate moiety by the 26 S complex.     

Thermal compensation in protein and RNA synthesis during the intermolt cycle of the American lobster, Homarus americanus.

1. The in vitro rates of incorporation of precursors into protein and RNA and the concentration of RNA were measured in tissues of intermolt and premolt lobsters acclimated to 5 degrees C and 20 degrees C. Midgut gland, abdominal muscle and gill of intermolt lobsters respond to temperature acclimation by a compensatory translation of the rate-temperature (R-T) curves with respect to the rates of incorporation of 3H-leucine and 3H-uridine into the acid-insoluble fraction. Midgut gland and muscle of premolt animals exhibit either no compensation or inverse compensation; gill tissue exhibits a rotation of the R-T curve. 2. The existence of the complete de novo pathway of pyrimidine biosynthesis is demonstrated in the class Crustacea. NaH14 CO2 is incorporated into orotic acid and orotic-14 C-acid is incorporated into the acid-insoluble fraction. 3. Both the concentration of RNA and the rates of incorporation of precursors of both the salvage and de novo pyrimidine pathways are enhanced in the midgut gland of premolt lobsters, relative to intermolt tissue, under conditions of warm-acclimation.     

In situ hybridization and immunocytochemistry in serial sections of rabbit skeletal muscle to detect myosin expression

We performed in situ hybridization of myosin heavy-chain (MHC) mRNA on rabbit muscle using a biotin-labeled complementary RNA probe. An 1107-nucleotide fragment from an alpha-cardiac MHC cDNA was used to transcribe an RNA probe 97% similar to slow-twitch and 75% similar to fast-twitch sequences. Serial sections were used to identify slow-twitch fibers in medial gastrocnemius, soleus, and tibialis anterior by immunofluorescence of slow MHC and oxidative capacity by histochemistry. Slow-twitch fibers hybridized by the RNA probe stained heavily after detection with streptavidin-alkaline phosphatase (89% dark and 11% medium density). Fast-oxidative fibers stained intermediately (26% dark, 58% medium, and 16% light) and fast-glycolytic fibers stained lightly (12% medium and 88% light). Biotin-labeled probe and enzymatic detection allowed greater resolution of the subcellular location of the MHC mRNA, a distinct advantage over isotope labeling and autoradiography. A non-uniform distribution of MHC mRNA was recognized within an adult skeletal muscle fiber. High concentrations of MHC mRNA were found under the sarcolemma and between the myofibrils, suggesting the existence of a distribution mechanism. The combination of in situ hybridization and immunocytochemistry allows rapid subcellular localization of both MHC mRNA and its translated protein.     

Ubiquitin chain trimming recycles the substrate binding sites of the 26 S proteasome and promotes degradation of lysine 48-linked polyubiquitin conjugates

The 26 S proteasome possesses two distinct deubiquitinating activities. The ubiquitin (Ub) chain amputation activity removes the entire polyUb chain from the substrates. The Ub chain trimming activity progressively cleaves a polyUb chain from the distal end. The Ub chain amputation activity mediates degradation-coupled deubiquitination. The Ub chain trimming activity can play a supportive or an inhibitory role in degradation, likely depending on features of the substrates. How Ub chain trimming assists degradation is not clear. We find that inhibition of the chain trimming activity of the 26 S proteasome with Ub aldehyde significantly inhibits degradation of Ub₄ (Lys-48)-UbcH10 and causes accumulation of free Ub₄ (generated from chain amputation) that can be retained on the proteasome. Also, a non-trimmable Lys-48-mimic Ub₄ efficiently targets UbcH10 to the 26 S proteasome, but it cannot support efficient degradation of UbcH10 compared with regular Lys-48 Ub₄. These results indicate that polyUb chain trimming promotes proteasomal degradation of Lys-48-linked substrates. Mechanistically, we propose that Ub chain trimming cleaves the proteasome-bound Lys-48-linked polyUb chains, which vacates the Ub binding sites of the 26 S proteasome, thus allowing continuous substrate loading.     

Immunocytochemical localization of actin and tubulin in the integument of land crab (Gecarcinus lateralis) and lobster (Homarus americanus)

The crustacean integument consists of the exoskeleton and underlying epithelium and associated tissues. The epithelium, which is composed of a single layer of cells, is responsible for the cyclical breakdown and synthesis of the exoskeleton associated with molting (ecdysis). During premolt (proecdysis) the epithelial cells lengthen and secrete the two outermost layers (epicuticle and exocuticle) of the new exoskeleton while partially degrading the two innermost layers (endocuticle and membranous layer) of the overlying old exoskeleton. This increased cellular activity is associated with increased protein synthesis and a change in cell shape from cuboidal to columnar. The cytoskeleton, composed of microfilaments (actin) and microtubules (tubulin), plays important roles in the intracellular organization and motility of eukaryotic cells. Immunoblot analysis shows that the land crab exoskeleton contains actin, tubulin, and actin-related proteins (Varadaraj et al. 1996. Gene 171:177-184). In the present study, immunocytochemistry of land crab and lobster integument showed that both proteins were localized in various cell types, including epithelia, connective tissue, tendinal cells, and blood vessels. Muscle immunostained for actin and myosin, but not for tubulin. The membranous layer of land crab (the other layers of the exoskeleton were not examined) and membranous layer and endocuticle of lobster also reacted specifically with anti-beta-actin and anti-alpha-tubulin monoclonal antibodies, but not with an anti-myosin heavy chain antibody. During proecdysis immunolabeling of the membranous layer decreased probably due to protein degradation. The staining intensity for actin and tubulin in the proecdysial epithelium was similar to that in the intermolt (anecdysial) epithelium, suggesting that there was a net accumulation of both proteins proportional to the increase in cellular volume. These results support the previous biochemical analyses and, more specifically, localize actin and tubulin in exoskeletal structures, suggesting that they may serve both intracellular and extracellular functions in crustaceans. J. Exp. Zool. 286:329-342, 2000.     

Claw asymmetry in lobsters: case study in developmental neuroethology.

An enduring debate in the study of development is the relative contribution of genetic and epigenetic factors in the genesis of an organism, that is, the nature vs. nurture debate. The behavior of the paired claws in the lobster offers promising material for pursuing this debate because of the way they develop. The paired claws and their closer muscles are initially symmetrical; both are slender in appearance and have a mixture of fast and slow fibers in their closer muscles. During a critical period of development, they become determined into a major (crusher) and minor (cutter) claw and during subsequent development acquire their final form and behavior: The crusher becomes a stout, molar-toothed claw capable of closing only slowly because its closer muscle has 100% slow fibers while the cutter becomes a slender, incisor-toothed claw capable of closing rapidly because its closer muscle has 90% fast fibers. Our initial hypothesis was that the more active claw became the crusher and its less active counterpart the cutter. Presumably, nerve activity would influence muscle transformation, which in turn would influence the exoskeleton to which they attach and hence claw morphology. Curtailing nerve activity to the claw prevented crusher development, while reflex activation of a claw promoted its development; both results support the notion that nerve activity directly regulates claw form and function. This is not, however, the case, for when both claws were reflexly exercised neither formed a crusher, signifying rather that bilateral differences in predominantly mechanoreceptive input to the paired claws somehow lateralized the claw ganglion [central nervous system (CNS)] into a crusher and cutter side. The side experiencing the greater activity becomes the crusher side while the contralateral side becomes the cutter and is also inhibited from ever becoming a crusher. This initial lateralization in the CNS is expressed, via as yet unknown pathways, at the periphery in claw morphology, muscle composition, and behavior. The critical period defines a time when the CNS is susceptible to being lateralized into a crusher and cutter side. Such lateralization is dependent upon experience of the environment in the form of mechanoreceptive input. In the absence of such experience, the CNS is not lateralized and paired cutter claws develop. Thus, while the critical period for crusher determination is genetically determined the actual trigger is influenced by experience.     

The claw closer muscle of Neohelice granulata (Grapsoidea,Varunidae): a morphological and histochemical study

Longo, M.V., Goldemberg, A.L. and Díaz, A.O. 2011. The claw closer muscle of Neohelice granulata (Grapsoidea, Varunidae): a morphological and histochemical study. —Acta Zoologica (Stockholm) 92 : 126–133. The claw closer muscle of Neohelice granulata was studied according to histological, histochemical, and morphometrical criteria. Adult male crabs in intermoult stage were collected from Mar Chiquita Lagoon (Buenos Aires, Argentina). Muscle fibers show evident striations and oval‐elongated nuclei with loose chromatin. The loose connective tissue among muscle fibers consists of cells and fibers embedded in an amorphous substance. Muscle histochemistry reveals two slow fiber types: ‘A’ and ‘B’. Prevailing A fibers are larger, and they usually show, with respect to B type, a weaker reaction to whole techniques. Fibers with short (SS), intermediate (IS), and long sarcomeres (LS) appear in the claw closer muscle, being the LS fibers predominant. Concluding, the histochemical and morphometrical characteristics of the claw closer muscle fibers of N. granulata are indicative of slow fibers. The slow A type (low resistant to fatigue) prevails.     

Influence of molt cycle and beta-ecdysone on protein synthesis in the chelicerate arthropod, Limulus polyphemus.

1. The effect of molt cycle stage and beta-ecdysone on protein synthesis in the horsehoe crab, Limulus polyphemus, was examined. 2. A pronounced decline in protein specific radioactivity after incubation with 14C-leucine was noted in muscle, midgut gland and operculum from postmolt to intermolt to premolt and in gut and gill tissue from intermolt to premolt. 3. beta-Ecdysone injections produced an early stimulation of protein synthesis in the midgut gland followed by strong inhibition within 48 hr. 4. Results are compared with those obtained in mandibulate arthropods.