Philip L. Hertzler

Development of the mesendoderm in the dendrobranchiate shrimp Sicyonia ingentis.

Dendrobranchiate shrimp embryos form a 4-cell stage that resembles spiralians in its cell contacts, but cleavage proceeds radially without any further evidence of spiralian character. The fates of Sicyonia ingentis mesendoblasts were followed by nuclear staining and confocal microscopy. The dorsal mesendoblast produced yolk-endoderm, which proliferated from the anterior of the embryo to cover the dorsal interior. The ventral mesendoblast divided into the primordial endoblast and a cell that further divided into the primordial mesoteloblast and the primordial germ cell. The primordial endoblast divided into left and right endoblasts, which then underwent two teloblastic divisions, leaving behind two pairs of smaller descendants and the larger endoblasts at the dorsal posterior. The endoblasts then paused in cell division while extensive morphogenesis occurred in the ectoderm to form the naupliar segments. Ectoteloblasts formed at the posterior. The primordial mesoteloblast underwent two asymmetric divisions, synchronously with the endoblasts, to form two small descendants and M2 at the ventral posterior. From 15 to 18h, M2 divided laterally then dorsal-ventrally to form four descendants. The results extend the cell lineage of S. ingentis from the egg to the nauplius larva, and demonstrate that endoderm forms dorsal to teloblastic mesoderm from an early stage.

Muscle development in dendrobranchiate shrimp, with comparison with Artemia.

SUMMARY The muscle pattern of malacostracan and entomostracan crustacean nauplius larvae was compared using fluorescent phallotoxins. In the dendrobranchiate malacostracan Sicyonia ingentis, F‐actin staining was first detected in limb setae at 12 h, likely within sensory nerves. Staining of F‐actin was detected in the trunk at 15 h and grew into the naupliar limbs. Sarcomeres were detected at 19 h, identifying the structures as extrinsic limb muscles. The extrinsic limb muscles enlarged but retained their general pattern during the later nauplius stages. Longitudinal trunk muscles and circumferential visceral muscle (VM) developed in the post‐naupliar region during nauplius instars 4 and 5, at the time when the gut also formed. In the anostracan branchiopod Artemia salina, the newly hatched nauplius contained an extensive system of extrinsic and intrinsic limb muscles. The gut was almost complete at hatching, along with its associated circumferential VM. Muscles similar in position and structure could be identified in nauplii from the two taxa, but different anatomical origins of extrinsic muscles were evident. Whether the naupliar limb muscles are homologous in malacostracans and branchiopods remains an open question. The strong musculature of the dendrobranchiate naupliar limbs correlates with the use of all three pairs of limbs for swimming.

Cleavage and gastrulation in the Kuruma shrimp Penaeus (Marsupenaeus) japonicus (Bate): A revised cell lineage and identification of a presumptive germ cell marker

A previous study suggested that mesendoderm (ME) cell arrest occurred at the 64‐cell stage and a ring of eight presumptive naupliar mesoderm cells or crown cells surrounded the blastopore in the Kuruma shrimp Penaeus (Marsupenaeus) japonicus. Since this varied from the pattern observed in other penaeoidean shrimp, cleavage and gastrulation was re‐examined in P. japonicus using the nucleic acid stain Sytox Green and confocal microscopy. In contrast to the earlier study, cleavage and gastrulation followed the pattern observed in other penaeoidean shrimp. The ME cells arrested at the 32‐cell stage, ingressed into the blastocoel, and resumed division after a three cell cycle delay. Nine naupliar mesoderm or crown cells surrounded the blastopore and their descendants invaginated during gastrulation. An intracellular body (ICB) was detected by Sytox Green and SYTO RNASelect staining to be segregated to one ME cell in P. japonicus, as described previously in Penaeus monodon. Staining of the ICB was eliminated by pre‐treatment with RNase but not DNase. The ICB was also found in two other penaeoidean shrimp, Penaeus vannamei (Family Penaeidae) and Sicyonia ingentis (Family Sicyoniidae). The results support the hypothesis that the ICB is a germ granule found in the Dendrobranchiata.

Transcriptome Profiles of Penaeus (Marsupenaeus) japonicus Animal and Vegetal Half-Embryos: Identification of Sex Determination, Germ Line, Mesoderm, and Other Developmental Genes

There is virtually no knowledge of the molecular events controlling early embryogenesis in Penaeid shrimp. A combination of controlled spawning environment, shrimp embryo micro-dissection techniques, and next-generation sequencing was used to produce transcriptome EST datasets of Penaeus japonicus animal and vegetal half-embryos. Embryos were collected immediately after spawning, and then blastomeres were separated at the two-cell stage and allowed to develop to late gastrulation, then pooled for RNA isolation and cDNA synthesis. Ion Torrent sequencing of cDNA from approximately 500 pooled animal and vegetal half-embryos from multiple spawnings resulted in 560,516 and 493,703 reads, respectively. Reads from each library were assembled and Gene Ontogeny analysis produced 3479 annotated animal contigs and 4173 annotated vegetal contigs, with 159/139 hits for developmental processes in the animal/vegetal contigs, respectively. Contigs were subject to BLAST for selected developmental toolbox genes. Some of the genes found included the sex determination genes sex-lethal and transformer; the germ line genes argonaute 1, boule, germ cell-less, gustavus, maelstrom, mex-3, par-1, pumilio, SmB, staufen, and tudor; the mesoderm genes brachyury, mef2, snail, and twist; the axis determination/segmentation genes β-catenin, deformed, distal-less, engrailed, giant, hairy, hunchback, kruppel, orthodenticle, patched, tailless, and wingless/wnt-8c; and a number of cell-cycle regulators. Animal and vegetal contigs were computationally subtracted from each other to produce sets unique to either half-embryo library. Genes expressed only in the animal half included bmp1, kruppel, maelstrom, and orthodenticle. Genes expressed only in the vegetal half included boule, brachyury, deformed, dorsal, engrailed, hunchback, spalt, twist, and wingless/wnt-8c.

Pleonal muscle development in the shrimp Penaeus (Litopenaeus) vannamei (Crustacea: Malacostraca: Decapoda: Dendrobranchiata)

Penaeoidean shrimp pleonal muscle is a valuable economic resource worldwide, but little is known of its development during larval stages. The development of pleonal muscle in Penaeus (Litopenaeus) vannamei was studied by rhodamine-phalloidin staining and laser-scanning confocal microscopy. Dorsal pleonal muscle was first evident at the protozoea I stage while ventral pleonal muscle was present by the protozoea II stage. Identifiable ventral pleonal muscles were evident by the protozoea III stage and all ventral muscle types were present in the mysis I. The tail flex response began at the mysis stage and growth of existing pleonal muscles continued. The pleopods formed during the mysis stages, with coxal and basis muscles developed by mysis III. The pleopods became functional beginning with the first post-larval stage. We conclude that the pleonal muscle pattern of P. vannamei larvae is similar to that of adult Penaeus setiferus, and that homologous muscles are present. The major formation of dorsal pleonal muscles occurs during the protozoea II stage, while significant development of ventral pleonal muscles occurs during the protozoea III stage.

Mesendoderm cells induce oriented cell division and invagination in the marine shrimp Sicyonia ingentis

The mesendoderm (ME) cells are the two most vegetal blastomeres in the early developing embryo of the marine shrimp Sicyonia ingentis. These two cells enter mitotic arrest for three cycles after the 5th cell cycle (32-cell stage) and ingress into the blastocoel at the 6th cycle (62-cell stage). Circumjacent to the ingressing ME cells are nine presumptive naupliar mesoderm (PNM) cells that exhibit a predictable pattern of spindle orientation into the blastopore, followed by invagination. We examined the role of ME cells and PNM cells in gastrulation using blastomere recombinations and confocal microscopy. Removal of ME progenitors prevented gastrulation. Removal of any other blastomeres, including PNM progenitors, did not interfere with normal invagination. Altered spindle orientations occurred in blastomeres that had direct contact with one of the ME cells; one spindle pole localized to the cytoplasmic region closest to ME cell contact. In recombined embryos, this resulted in an extension of the region of ME-embryo contact. Our results show that ME cells direct the spindle orientations of their adjacent cells and are consistent with a mechanism of oriented cell division being a responsible force for archenteron elongation.

Ultrastructure of putative germ granules in the penaeid shrimp Marsupenaeus japonicus

Knowledge about the specification of the germ line in penaeid shrimp would allow development of techniques to control germ cell formation and/or fate to produce reproductively sterile shrimp for genetic copyright purposes. Recent studies have traced the localization of an RNA-enriched intracellular body (ICB) in the putative germ line of four penaeid shrimp species. It is hypothesized that the ICB may serve as a putative germ granule and marker of germ line fate. In this study semi-thin and ultra-thin sections of Marsupenaeus japonicus embryos were prepared, and the dimensions and ultrastructure of the ICB was examined at different stages of embryogenesis. The ICB was an aggregation of electron dense granules, small vesicles and multi-vesicular bodies (MVBs), similar to germ granules from other species. Lamellar membranes and mitochondria were localized at the periphery of the ICB. Using fluorescence microscopy, microtubules were also observed between the centrosome and the ICB. The localization of the ICB in the D lineage and putative germ cell line, the enrichment of RNA in the ICB, and the ultrastructural similarities to other germ granules characterized in this study support the hypothesis that the ICB contains germ granules.

Expression of the prospective mesoderm genes twist, snail, and mef2 in penaeid shrimp

In penaeid shrimp, mesoderm forms from two sources: naupliar mesoderm founder cells, which invaginate during gastrulation, and posterior mesodermal stem cells called mesoteloblasts, which undergo characteristic teloblastic divisions. The primordial mesoteloblast descends from the ventral mesendoblast, which arrests in cell division at the 32-cell stage and ingresses with its sister dorsal mesendoblast prior to naupliar mesoderm invagination. The naupliar mesoderm forms the muscles of the naupliar appendages (first and second antennae and mandibles), while the mesoteloblasts form the mesoderm, including the muscles, of subsequently formed posterior segments. To better understand the mechanism of mesoderm and muscle formation in penaeid shrimp, twist, snail, and mef2 cDNAs were identified from transcriptomes of Penaeus vannamei, P. japonicus, P. chinensis, and P. monodon. A single Twist ortholog was found, with strong inferred amino acid conservation across all three species. Multiple Snail protein variants were detected, which clustered in a phylogenetic tree with other decapod crustacean Snail sequences. Two closely-related mef2 variants were found in P. vannamei. The developmental mRNA expression of these genes was studied by qPCR in P. vannamei embryos, larvae, and postlarvae. Expression of Pv-twist and Pv-snail began during the limb bud stage and continued through larval stages to the postlarva. Surprisingly, Pv-mef2 expression was found in all stages from the zygote to the postlarva, with the highest expression in the limb bud and protozoeal stages. The results add comparative data on the development of anterior and posterior mesoderm in malacostracan crustaceans, and should stimulate further studies on mesoderm and muscle development in penaeid shrimp.

“Crustacea”: Decapoda (Dendrobranchiata)

The Decapoda consists of two taxa, the Dendrobranchiata, which include the penaeoid and sergestoid shrimps, and the Pleocyemata including the caridean shrimp, lobsters, and crabs. Four characters distinguish the Dendrobranchiata: (1) “dendrobranchiate” gill structure, (2) different patterning of the first three pairs of pereopods (walking limbs), (3) lateral flaps (pleura) of the second abdominal somite nonoverlapping with the first somite, and (4) eggs freely spawned versus carried on the abdominal pleopods (Dall et al. 1990). The dendrobranchiate shrimp are of interest both for commercial importance as food and for their significance as a taxon of decapod crustaceans showing many supposedly plesiomorphic characters.

Penaeid shrimp brachyury: sequence analysis and expression during gastrulation

Gastrulation occurs by a variety of morphogenetic movements, often correlated with diverse expression of the T-box transcription factor Brachyury (Bra). Bra may be expressed in ectoderm, mesoderm, or endoderm, but its role in cell fate specification or regulation of gastrulation movements has not been studied in the development of crustaceans. Penaeid shrimp (Decapoda: Dendrobranchiata: Penaeidae) develop by complete cleavage and gastrulation by invagination to a free-swimming nauplius larva. Penaeid gastrulation diverges from other decapods and from insects, occurring early at a low cell number with the formation of a radial invagination. Toward a better understanding of gastrulation movements in penaeid shrimp, bra was identified from newly available penaeid shrimp genomes and transcriptomes of Litopenaeus vannamei, Marsupenaeus japonicus, and Penaeus monodon. Additional bra homologs were obtained from the outgroups Sicyonia ingentis (Decapoda: Dendrobranchiata: Sicyoniidae) and the caridean shrimp Caridina multidentata (Decapoda: Pleocymata). The genes encoded penaeid shrimp Bra proteins of 551–552 amino acids, containing the highly conserved T-box DNA-binding region. The N-terminal Smad1-binding domain, conserved in most animals, was absent in shrimp Bra. The R1 repressor domain was the best conserved of the C-terminal regulatory domains, which were widely divergent compared to other species. The penaeid shrimp bra gene consisted of six exons, with splice sites conserved with other phyla across the animal kingdom. Real-time qPCR and FPKM analysis showed that shrimp bra mRNA was strongly expressed during gastrulation. These findings begin to address the evolution of gastrulation in shrimp at the molecular level.