Why Do Sleeping Nematodes Adopt a Hockey-Stick-Like Posture?

A characteristic posture is considered one of the behavioral hallmarks of sleep, and typically includes functional features such as support for the limbs and shielding of sensory organs. The nematode C. elegans exhibits a sleep-like state during a stage termed lethargus, which precedes ecdysis at the transition between larval stages. A hockey-stick-like posture is commonly observed during lethargus. What might its function be? It was previously noted that during lethargus, C. elegans nematodes abruptly rotate about their longitudinal axis. Plausibly, these “flips” facilitate ecdysis by assisting the disassociation of the old cuticle from the new one. We found that body-posture during lethargus was established using a stereotypical motor program and that body bends during lethargus quiescence were actively maintained. Moreover, flips occurred almost exclusively when the animals exhibited a single body bend, preferentially in the anterior or mid section of the body. We describe a simple biomechanical model that imposes the observed lengths of the longitudinally directed body-wall muscles on an otherwise passive elastic rod. We show that this minimal model is sufficient for generating a rotation about the anterior-posterior body axis. Our analysis suggests that posture during lethargus quiescence may serve a developmental role in facilitating flips and that the control of body wall muscles in anterior and posterior body regions are distinct.     

Molting-specific downregulation of C. elegans body-wall muscle attachment sites: The role of RNF-5 E3 ligase

Repeated molting of the cuticula is an integral part of arthropod and nematode development. Shedding of the old cuticle takes place on the surface of hypodermal cells, which are also responsible for secretion and synthesis of a new cuticle. Here, we use the model nematode Caenorhabditis elegans to show that muscle cells, laying beneath and mechanically linked to the hypodermis, play an important role during molting. We followed the molecular composition and distribution of integrin mediated adhesion structures called dense bodies (DB), which indirectly connect muscles to the hypodermis. We found the concentration of two DB proteins (PAT-3/β-integrin and UNC-95) to decrease during the quiescent phase of molting, concomitant with an apparent increase in lateral movement of the DB. We show that levels of the E3-ligase RNF-5 increase specifically during molting, and that RNF-5 acts to ubiquitinate the DB protein UNC-95. Persistent high levels of RNF-5 driven by a heatshock or unc-95 promoter lead to failure of ecdysis, and in non-molting worms to a progressive detachment of the cuticle from the hypodermis. These observations indicate that increased DB dynamics characterizes the lethargus phase of molting in parallel to decreased levels of DB components and that temporal expression of RNF-5 contributes to an efficient molting process.     

The dauerlarva, a post-embryonic developmental variant of the nematode Caenorhabditis elegans.

In the postembryological development of the free-living nematode Caenorhabditis elegans, a morphologically recognizable, nongrowing stage, called the dauerlarva, may arise. Using synchronous populations and following growth and molting, it has been shown that the dauerlarva is formed by a facultative, reversible arrest at a specific point in the life cycle, the second of four cuticle molts, in response to external conditions.At each molt a normal animal passes through “lethargus,” a stage in which feeding and locomotion are transiently arrested. In the dauerlarva stage, feeding is arrested indefinitely and locomotion is markedly reduced. A simple quantitative assay, based on the exceptional resistance of dauerlarvae to sodium dodecyl sulfate (SDS), has been developed to study dauerlarva formation and its reversal. The SDS resistance of dauerlarvae requires both non-feeding and an especially impermeable cuticle. Dauerlarva formation can be efficiently induced by limiting the concentration of bacteria (the food supply), but not by complete starvation. Quantitative recovery to normal development can be induced by transfer to fresh medium with excess bacteria. Simpler stimuli can elicit recovery at slower rates, the principal factors besides nutrition being nutrition being optimal ionic and osmotic conditions and a noninhibitory concentration of animals. There are identifiable stages in recovery, beginning with a resumption of feeding. The cuticle, ultrastructurally very different from normal cuticle, is shed at the next molt, after which development appears normal. A temperature-sensitive mutant, which forms dauerlarvae at high temperature despite the presence of abundant food, is described, and the use of dauerlarvae for further mutant isolation is discussed.     

中国米虾bursicon基因的功能及作用机制

为探讨米虾鞣化激素在其蜕皮周期及表皮角质层形成过程中的作用, 采用PCR技术克隆得到了米虾鞣化激素两个亚基基因的开放阅读框(ORF)序列。bursicon-α ORF全长441 bp, 共编码146个氨基酸; bursicon-β ORF全长411 bp, 共编码136个氨基酸。利用实时荧光定量PCR分析米虾整个蜕皮周期中鞣化激素2个亚基基因的表达特征, 结果发现, 鞣化激素bursicon-α和bursicon-β在米虾蜕皮周期的各个阶段的相对表达量存在差异, 在蜕皮前期(D期)相对表达量开始上升, 到D₃期时相对表达量最高, 蜕皮期E期相对表达量最低。RNA干扰(RNA interference, RNAi)介导bursicon-α和bursicon-β基因沉默后, 发现米虾的蜕皮周期延长, 表皮角质层明显变薄。结果提示, 鞣化激素(Bursicon)与新形成的外骨骼中角质层的加厚与硬化密切相关, 进而影响蜕皮时间。     

Cuticle Formation in Hemicycliophora arenaria,Aphelenchus avenae and HirschmannIella gracilis

The onset of molting in all stages of Hemicycliophora arenaria was preceded by the appearance of numerous, discrete globular structures which were termed "molting bodies" because they were present in the hypodermis only during the production of the new cuticle. In all parasitic stages the molt commenced with the separation of the cuticle from the hypodermis from which the new sheath and cuticle were differentiated. Following completion of the new sheath and cuticle most of the old outer covering was apparently absorbed before ecdysis. Electronmicrographs of body wall cross sections in molting L4 male specimens revealed the final molt to be a double molt in which an additional sixth cuticle was produced. Since both a new sheath and cuticle were produced during the molt of each stage, the sheath must be considered as an integral part of the cuticle and not as a residual cuticle or the result of an incomplete additional molt. Molting in Aphelenchus avenae and Hirschmanniella gracilis was less complex and "molting bodies" were not observed. After cuticle separation the hypodermis gave rise to a new trilaminate zone, the future cortex, and (later) the matrix and striated basal layers.     

Small Collagenous Proteins Present during the Molt in Caenorhabditis elegans

Immunoblotting experiments using antibodies directed against the large collagenous cuticle proteins of Caenorhabditis elegans revealed a class of small collagenous proteins (CP) of apparent molecular weight 38,000-52,000 present during the L4 to adult molt. These CP are smaller than most vertebrate collagens characterized to date and share many characteristics with the small collagenous products translated in vitro from RNA isolated at this molt. C. elegans collagen genes, collagen-coding mRNA, and collagenous in vitro products that have been characterized are also small. Detection of small CP in vivo in C. elegans thus lends further support to the hypothesis that such small collagenous proteins are the primary gene product precursors to the larger collagenous proteins isolated from the C. elegans cuticle.     

The molt cycle and its hormonal control in Rhithropanopeus harrisii larvae

Stages of the zoeal and megalopal molt cycles of Rhithropanopeus harrisii were characterized by the appearance of epidermal cells in the spines and antennae. Eyestalk removal of the beginning of the last zoeal instar slightly accelerated the molt cycle. Fourth-instar larvae which had undergone eyestalk ablation during the third instar progressed through the molt cycle significantly faster than did control larvae. Eyestalkless megalopae also demonstrated an enhanced molting rate. The results suggested that the larval eyestalks contain a factor (molt-inhibiting hormone) which plays a role in controlling the molting rate.     

New Functions of Arthropod Bursicon: Inducing Deposition and Thickening of New Cuticle and Hemocyte Granulation in the Blue Crab,Callinectes sapidus

Arthropod growth requires molt-associated changes in softness and stiffness of the cuticle that protects from desiccation, infection and injury. Cuticle hardening in insects depends on the blood-borne hormone, bursicon (Burs), although it has never been determined in hemolymph. Whilst also having Burs, decapod crustaceans reiterate molting many more times during their longer life span and are encased in a calcified exoskeleton, which after molting undergoes similar initial cuticle hardening processes as in insects. We investigated the role of homologous crustacean Burs in cuticular changes and growth in the blue crab, Callinectes sapidus. We found dramatic increases in size and number of Burs cells during development in paired thoracic ganglion complex (TGC) neurons with pericardial organs (POs) as neurohemal release sites. A skewed expression of Burs β/Burs α mRNA in TGC corresponds to protein contents of identified Burs β homodimer and Burs heterodimer in POs. In hemolymph, Burs is consistently present at ∼21 pM throughout the molt cycle, showing a peak of ∼89 pM at ecdysis. Since initial cuticle hardness determines the degree of molt-associated somatic increment (MSI), we applied recombinant Burs in vitro to cuticle explants of late premolt or early ecdysis. Burs stimulates cuticle thickening and granulation of hemocytes. These findings demonstrate novel cuticle-associated functions of Burs during molting, while the unambiguous and constant presence of Burs in cells and hemolymph throughout the molt cycle and life stages may implicate further functions of its homo- and heterodimer hormone isoforms in immunoprotective defense systems of arthropods.     

Biochemistry of insect differentiation: A system for studying the mechanism of chitinase activity in vitro

Results obtained with an in vitro system for the study of chitinase are described. The system involves soluble enzyme protein(s) and an insoluble substrate preparation. With insect molting fluid chitinase, it shows properties that parallel those observed during in vivo breakdown of cuticle during the molt. For example, molting fluid chitinase activity not previously exposed to chitin is stronly and specifically adsorbed to the substrate, in contrast to other enzymatic activities including hexosaminidase (chitobiase) present in molting fluid. This leads to partial purification of molting fluid chitinase activity reflected in increased specific activity of chitinase associated with the insoluble chitin substrate; we have previously reported increase of specific chitinase activity of (deproteinized) cuticle resulting from its incubation with molting fluid (M. L. Bade and A. Stinson, 1978, Biochem. Biophys. Res. Commun.84, 381–388). Soluble end product is generated rapidly and linearly with time by the in vitro system; the end product is assumed to be N-acetylglucosamine since the specific radioactivity of this compound is unchanged during the 10 min required for assay. Molting fluid chitinase activity may involve a number of polypeptides ranging in molecular weight from 145,000 to less than 20,000 daltons. The system described gives results consistent with a processive mechanism for molting fluid chitinase, i.e., data are given demonstrating that molting fluid chitinase continues to act on the same chitin particle(s) with which it initially associates rather than diffusing freely from substrate particle to substrate particle, and the product of its action appears to be a monosaccharide rather than a mixture of oligosaccharides. Processive behavior for chitinase would be predicted from the known structure, and the in vivo measured rate of breakdown, of cuticle chitin during the molt; the preliminary nature of this conclusion, based on what is so far known about the structure of the substrate used in the in vitro system, is briefly discussed.     

Histological and ultrastructural studies of Beauveria bassiana infection in Leptinotarsa decemlineta larvae during ecdysis

Studies of Leptinotarsa decemlineata larvae infected by Beauveria bassiana during ecdysis have enabled us to define the modes of fungal penetration employed to enter the ecdysial cuticle. We have observed the mechanically active passage of the penetrant hyphae and have followed the growth of the filaments and blastospore formation in the molting fluid. The attack of the new integument and its consequent alteration and the entry into the body cavity have also been studied. The infection develops rapidly in some of the larvae which die in premolt, while others are able to molt. Conditions rendered abnormal due to the presence of the fungus cause integumentary injuries which serve as an important factor in pathogenesis since they enhance the entry of fungal elements and bacteria thereby inducing septicemia. Contaminated larvae are able to molt, showing no signs of injury or disease, and survive for a long time, until the fungus finally invades the organism and causes death. This postponement of mortality shows that molting and hemocytic reactions are, to a certain extent, an effective defense mechanism. These last observations can be useful in the understanding of pathological processes associated with a hidden phase of fungal infection.     

Reduced activity of a sensory neuron during a sleep-like state in Caenorhabditis elegans

Sleep-like states occur in the life of all animals carefully studied and are characterized by reduced behavioral and neural activity as well as reduced responsiveness to stimulation [1]. How is reduced responsiveness to stimulation generated? We used calcium imaging to investigate a sleep-like state in larvae of the nematode Caenorhabditis elegans. We found that overall spontaneous neural activity was reduced during the sleep-like state in many neurons, including the mechanosensory neuron ALM. Stimulus-evoked calcium transients and behavior were reduced in ALM during the sleep-like state. Thus, reduced activity of ALM may contribute to reduce responsiveness during a sleep-like state.     

Functional Analysis of Insect Molting Fluid Proteins on the Protection and Regulation of Ecdysis

Molting fluid accumulates between the old and new cuticles during periodical ecdysis in Ecdysozoa. Natural defects in insect ecdysis are frequently associated with melanization (an immunity response) occurring primarily in molting fluids, suggesting that molting fluid may impact immunity as well as affect ecdysis. To address this hypothesis, proteomic analysis of molting fluids from Bombyx mori during three different types of ecdysis was performed. Many proteins were newly identified, including immunity-related proteins, in each molting fluid. Molting fluids inhibited the growth of bacteria in vitro. The entomopathogenic fungi Beauveria bassiana, which can escape immune responses in feeding larvae, is quickly recognized by larvae during ecdysis, followed by melanization in molting fluid and old cuticle. Fungal conidia germination was delayed, and no hyphae were detected in the hemocoels of pharate instar insects. Molting fluids protect the delicate pharate instar insects with extremely thin cuticles against microorganisms. To explore the function of molting fluids in ecdysis regulation, based on protein similarity, 32 genes were selected for analysis in ecdysis regulation through RNAi in Tribolium castaneum, a model commonly used to study integument development because RNAi is difficult to achieve in B. mori. We identified 24 molting proteins that affected ecdysis after knockdown, with different physiological functions, including old cuticle protein recycling, molting fluid pressure balance, detoxification, and signal detection and transfer of molting fluids. We report that insects secrete molting fluid for protection and regulation of ecdysis, which indicates a way to develop new pesticides through interrupting insect ecdysis in the future.     

Cuticular protein LmTwdl1 is involved in molt development of the migratory locust

The cuticle, an essential structure for insects, is produced from cuticular proteins and chitin via a series of biochemical reactions. Tweedle genes are important members of the cuticular protein family and have four conserved motifs binding to chitin. Tweedle family genes have been found to play a profound effect on cuticle development. Here, we report that the cuticular protein gene LmTwdl1 of Locusta migratoria belongs to the Tweedle family. In situ hybridization showed that LmTwdl1 is localized to epidermal cells of the cuticle. The expression patterns of LmTwdl1 showed low expression in the cuticle during the early and middle stages of the fifth‐instar nymphs; in contrast, its expression rapidly increased in the late stages of fifth‐instar nymphs. We performed RNA interference to examine the function of LmTwdl1 in locusts. Silencing of LmTwdl1 resulted in high mortality during the molting process before the next stage. Also, the epicuticle of nymphs failed to molt, tended to be thinner and the arrangement of chitin in the procuticle appeared to be disordered compare to the control group. These results demonstrate that LmTwdl1 plays a critical role in molting, which contributes to a better understanding of the distinct functions of the Tweedle family in locusts.     

Behavioral and genomic characterization of molt-sleep in the tobacco hornworm,Manduca sexta

During the transition from feeding to molting, larval insects undergo profound changes in behavior and patterns of gene expression regulated by the neuroendocrine system. For some species, a distinctive characteristic of molting larvae is presence of a quiescent state sometimes referred to as “molt-sleep”. Here, observations of 4th instar Manduca sexta larvae indicate the molting period involves a predominantly quiescent state that shares behavioral properties of adult insect sleep in that it is rapidly reversible and accompanied by a reduced responsiveness to both mildly arousing and noxious stimuli. When subjected to noxious stimuli, molting larvae exhibit locomotory and avoidance behaviors similar to those of inter-molt larvae. Although less consolidated, inter-molt quiescence shares many of the same behavioral traits with molting quiescence. However, when subjected to deprivation of quiescence, inter-molt larvae display a compensatory rebound behavior that is not detected in molting larvae. This suggests that molting quiescence is a specialized form of inactivity that affords survival advantages to molting larvae. RNA-seq analysis of molting larvae shows general reduction in expression of genes encoding GPCRs and down regulation of genes connected with cyclic nucleotide signaling. On the other hand, certain ion channel genes are up-regulated, including transient receptor potential (TRP) channels, chloride channels and a voltage-dependent calcium channel. These findings suggest patterns of gene expression consistent with elevation of quiescent state characteristic of the molt in a model holometabolous insect.