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28.4B: Phylum Nematoda

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Nematodes are parasitic and free-living worms that are able to shed their external cuticle in order to grow.

Learning Objectives

• Describe the features of animals classified in phylum Nematoda
• Nematodes are in the same phylogenetic grouping as the arthropods because of the presence of an external cuticle that protects the animal and keeps it from drying out.
• There are an estimated 28,000 species of nematodes, with approximately 16,000 of them being parasitic.
• Nematodes are tubular in shape and are considered pseudocoelomates because of they do not possess a true coelom.
• Nematodes do not have a well-developed excretory system, but do have a complete digestive system.
• Nematodes possess the ability to shed their exoskeleton in order to grow, a process called ecdysis.
• exoskeleton : a hard outer structure that provides both structure and protection to creatures such as insects, Crustacea, and Nematoda

Phylum Nematoda

The Nematoda, similar to most other animal phyla, are triploblastic, possessing an embryonic mesoderm that is sandwiched between the ectoderm and endoderm. They are also bilaterally symmetrical: a longitudinal section will divide them into right and left sides that are symmetrical. Furthermore, the nematodes, or roundworms, possess a pseudocoelom and have both free-living and parasitic forms.

Both the nematodes and arthropods belong to the superphylum Ecdysozoa that is believed to be a clade consisting of all evolutionary descendants from one common ancestor. The name derives from the word ecdysis, which refers to the shedding, or molting, of the exoskeleton. The phyla in this group have a hard cuticle covering their bodies, which must be periodically shed and replaced for them to increase in size.

Phylum Nematoda includes more than 28,000 species with an estimated 16,000 being parasitic in nature. Nematodes are present in all habitats.

In contrast with cnidarians, nematodes show a tubular morphology and circular cross-section. These animals are pseudocoelomates; they have a complete digestive system with a distinct mouth and anus. This is in contrast with the cnidarians where only one opening is present (an incomplete digestive system).

The cuticle of Nematodes is rich in collagen and a carbohydrate-protein polymer called chitin. It forms an external “skeleton” outside the epidermis. The cuticle also lines many of the organs internally, including the pharynx and rectum. The epidermis can be either a single layer of cells or a syncytium, which is a multinucleated cell formed from the fusion of uninucleated cells.

The overall morphology of these worms is cylindrical, while the head is radially symmetrical. A mouth opening is present at the anterior end with three or six lips. Teeth occur in some species in the form of cuticle extensions. Some nematodes may present other external modifications such as rings, head shields, or warts. Rings, however, do not reflect true internal body segmentation. The mouth leads to a muscular pharynx and intestine, which leads to a rectum and anal opening at the posterior end. In addition, the muscles of nematodes differ from those of most animals; they have a longitudinal layer only, which accounts for the whip-like motion of their movement.

Excretory System

In nematodes, specialized excretory systems are not well developed. Nitrogenous wastes may be lost by diffusion through the entire body or into the pseudocoelom (body cavity), where they are removed by specialized cells. Regulation of water and salt content of the body is achieved by renette glands, present under the pharynx in marine nematodes.

Nervous system

Most nematodes possess four longitudinal nerve cords that run along the length of the body in dorsal, ventral, and lateral positions. The ventral nerve cord is better developed than the dorsal or lateral cords. All nerve cords fuse at the anterior end, around the pharynx, to form head ganglia, or the “brain” of the worm (taking the form of a ring around the pharynx), as well as at the posterior end to form the tail ganglia. In C. elegans , the nervous system accounts for nearly one-third of the total number of cells in the animal.

Reproduction

Nematodes employ a variety of reproductive strategies that range from monoecious to dioecious to parthenogenic, depending upon the species under consideration. C. elegans is a monoecious species, having development of ova contained in a uterus as well as sperm contained in the spermatheca. The uterus has an external opening known as the vulva. The female genital pore is near the middle of the body, whereas the male’s is at the tip. Specialized structures at the tail of the male keep him in place while he deposits sperm with copulatory spicules. Fertilization is internal with embryonic development beginning very soon after fertilization. The embryo is released from the vulva during the gastrulation stage. The embryonic development stage lasts for 14 hours; development then continues through four successive larval stages with ecdysis between each stage (L1, L2, L3, and L4) ultimately leading to the development of a young male or female adult worm. Adverse environmental conditions such as overcrowding and lack of food can result in the formation of an intermediate larval stage known as the dauer larva.

Chapter 15 Nematode Study Guide The test will consist of 30

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Module 11: Invertebrates

Phylum nematoda, learning outcomes.

• Describe the features of animals classified in phylum Nematoda

The Nematoda, like most other animal phyla, are triploblastic and possess an embryonic mesoderm that is sandwiched between the ectoderm and endoderm. They are also bilaterally symmetrical, meaning that a longitudinal section will divide them into right and left sides that are symmetrical. Furthermore, the nematodes, or roundworms, possess a pseudocoelom and consist of both free-living and parasitic forms.

It has been said that were all the non-nematode matter of the biosphere removed, there would remain a shadow of the former world in the form of nematodes. [1]  The arthropods, one of the most successful taxonomic groups on the planet, are coelomate organisms characterized by a hard exoskeleton and jointed appendages. Both the nematodes and arthropods belong to the superphylum Ecdysozoa that is believed to be a clade consisting of all evolutionary descendants from one common ancestor. The name derives from the word ecdysis, which refers to the shedding, or molting, of the exoskeleton. The phyla in this group have a hard cuticle that covers their bodies, which must be periodically shed and replaced for them to increase in size.

Phylum  Nematoda  includes more than 28,000 species with an estimated 16,000 being parasitic in nature. The name Nematoda is derived from the Greek word “Nemos,” which means “thread” and includes roundworms. Nematodes are present in all habitats with a large number of individuals of each species present in each. The free-living nematode,  Caenorhabditis elegans  has been extensively used as a model system in laboratories all over the world.

In contrast with flatworms, nematodes show a tubular morphology and circular cross-section. These animals are pseudocoelomates and show the presence of a complete digestive system with a distinct mouth and anus. This is in contrast with the cnidarians, where only one opening is present (an incomplete digestive system).

The cuticle of Nematodes is rich in collagen and a carbohydrate-protein polymer called chitin, and forms an external “skeleton” outside the epidermis. The cuticle also lines many of the organs internally, including the pharynx and rectum. The epidermis can be either a single layer of cells or a syncytium, which is a multinucleated cell formed from the fusion of uninucleated cells.

The overall morphology of these worms is cylindrical, as seen in Figure 1. The head is radially symmetrical. A mouth opening is present at the anterior end with three or six lips as well as teeth in some species in the form of cuticle extensions. Some nematodes may present other external modifications like rings, head shields, or warts. Rings, however, do not reflect true internal body segmentation. The mouth leads to a muscular pharynx and intestine, which leads to a rectum and anal opening at the posterior end. The muscles of nematodes differ from those of most animals: They have a longitudinal layer only, which accounts for the whip-like motion of their movement.

Figure 1. Scanning electron micrograph shows (a) the soybean cyst nematode ( Heterodera glycines ) and a nematode egg. (b) A schematic representation shows the anatomy of a typical nematode. (credit a: modification of work by USDA ARS; scale-bar data from Matt Russell)

Excretory System

In nematodes, specialized excretory systems are not well developed. Nitrogenous wastes may be lost by diffusion through the entire body or into the pseudocoelom (body cavity), where they are removed by specialized cells. Regulation of water and salt content of the body is achieved by renette glands, present under the pharynx in marine nematodes.

Nervous System

Most nematodes possess four longitudinal nerve cords that run along the length of the body in dorsal, ventral, and lateral positions. The ventral nerve cord is better developed than the dorsal or lateral cords. All nerve cords fuse at the anterior end, around the pharynx, to form head ganglia or the “brain” of the worm (which take the form of a ring around the pharynx) as well as at the posterior end to form the tail ganglia. In  C .  elegans , the nervous system accounts for nearly one-third of the total number of cells in the animal.

Reproduction

Nematodes employ a variety of reproductive strategies that range from monoecious to dioecious to parthenogenic, depending upon the species under consideration.  C .  elegans  is a monoecious species and shows development of ova contained in a uterus as well as sperm contained in the spermatheca. The uterus has an external opening known as the vulva. The female genital pore is near the middle of the body, whereas the male’s is at the tip. Specialized structures at the tail of the male keep him in place while he deposits sperm with copulatory spicules. Fertilization is internal, and embryonic development starts very soon after fertilization. The embryo is released from the vulva during the gastrulation stage. The embryonic development stage lasts for 14 hours; development then continues through four successive larval stages with ecdysis between each stage—L1, L2, L3, and L4—ultimately leading to the development of a young male or female adult worm. Adverse environmental conditions like overcrowding and lack of food can result in the formation of an intermediate larval stage known as the dauer larva.

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• Stoll, N. R., “This wormy world. 1947,” Journal of Parasitology 85(3) (1999): 392–96. ↵
• Biology 2e. Provided by : OpenStax. Located at : http://cnx.org/contents/[email protected] . License : CC BY: Attribution . License Terms : Access for free at https://openstax.org/books/biology-2e/pages/1-introduction

Introduction to Nematodes

    Zullini and Semprucci compared the characteristics of soil inhabiting and freshwater-inhabiting nematodes.   They noted that aquatic (=open water)   and semiaquatic species are, on average, longer and slimmer than soil species, they have a longer tail, greater body weight, smooth cuticle and larger amphids.   Usually, but not always, nematodes living in and on freshwater sediments are characterized by:

i)                      Long cephalic and somatic setae . Setae are essentially useful sensory devices. The restrictive thickness of the water film around soil particles would inhibit their function in soil. Consequently,, they are generally reduced or absent in soil-inhabiting   species. However, they are not always present in freshwater species. Freshwater species lacking setae, such as Dorylaimida, Mononchida and Rhabditida, are closely related to soil species

ii)                    Large amphids. Chemoreceptor organs such as amphids perform a different role in soil solution which is rich in salts and dissolved organic matter and where the chemical information travels a very short distance. In open fresh water, usually less rich in dissolved substances, the chemical signal travels long distances and quite rapidly. The signal strength changes slowly in soil but dissipates faster in open water. Soil species, and freshwater species related to soil species, usually have small, sometimes punctiform, amphids.

iii)                  Ocelli. Light receptors are fairly common in marine nematodes but are rare in freshwater species. In soil species, they are generally absent

iv)             Caudal glands and spinneret . Glands secreting a sticky substance through the spinneret, for anchoring the tip of the tail, are useful for nematodes living at the surface of the sediment to avoid the effect of water currents. Not all aquatic species have caudal glands and spinnerets,

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DisplayTitle Nematodes - the good, the bad and the ugly.

Frank S. Hay University of Tasmania

Some nematodes feed on plants and are commonly referred to as ‘eelworms’ in the British-speaking world. Most plant nematodes are less than 1 mm long and almost invisible to the eye. They may not impress you the way the sperm whale nematode would, but they are responsible for some 15% loss to crops per annum world-wide, equating to some US$78 billion! Plant feeding nematodes have a sharp needle-like structure in their mouth called a ‘stylet’ (Fig 2A, 2B). The stylet acts like a very small hypodermic needle and is used to pierce through cell walls and suck out the cell contents. An example of the losses caused by eelworms is the pine wilt nematode ( Bursaphelenchus xylophilus ) which has been associated with the death of tens of millions of pine trees in Japan. How can something less than 1 mm long cause such devastation? The answer lies in reproduction, with the nematode reaching populations of billions per tree. That’s a lot of hungry mouths!

Most plant feeding nematodes live in the soil and feed on plant roots, thereby reducing the plant’s uptake of water and nutrients, and reducing tolerance to other stresses such as drought. Some transmit other disease causing agents (e.g. viruses) to plants as they feed. When numbers of eelworms get too high in the soil, farmers sometimes apply chemicals called fumigants or nematicides to the soil to control them. However, these chemicals are generally very toxic and hazardous to the health of both humans and the environment. Some nematicides have been banned because they were found to easily leach through the soil and contaminate drinking water in aquifers.

Fortunately, most species of nematodes have no effect, or have a beneficial effect, on humans and their endeavours. Many species of nematodes are ‘free-living’, living in soil, sea and freshwater. These feed on bacteria, fungi, protozoans and even other nematodes, and play a very important role in nutrient cycling and release of nutrients for plant growth. Other nematodes attack insects, and help to control insect pests. In fact, some nematodes which attack insect pests are reared commercially and released for the control of certain insect pests as a biological insecticide. A nematode released to control the Sirex wood wasp has been credited with saving the forestry industry up to 80 million US dollars per year in Australia.

Nematodes are also important in other ways. The nematode Caenorhabditis elegans was the first multi-cellular organism to have its DNA fully sequenced. This has led to many exciting breakthroughs in the biological and medical sciences in the last few years. This nematode is also famous in that some individuals, being carried onboard as part of an experiment, survived the Space Shuttle Columbia disaster in 2003!

Nematodes can be found from the depths of the ocean to mountain tops. A spadeful of soil can contain more than a million nematodes! Because nematodes are so numerous and occur in so many habitats, it has been suggested that if we removed everything from our planet but nematodes, much of the topography of the Earth would still be recognisable as a film of nematodes!

So while nematodes are generally small and often unnoticeable, they have an enormous impact on us and our world. Watch out for them!

Further Resources:

For further general information on nematodes follow this link: http://www.apsnet.org/edcenter/K-12/TeachersGuide/Nematode/Pages/MaterialsandMethods.aspx

For further information on plant-parasitic nematodes follow this link: http://www.apsnet.org/edcenter/intropp/PathogenGroups/Pages/IntroNematodes.aspx

Further information on the sequencing of the genome of Caenorhabditis elegans can be found at: http://www.apsnet.org/publications/apsnetfeatures/Pages/Celegans.aspx

Answer to question about Figure 1: Caenorhabditis elegans is not a plant parasitic nematode; it does NOT have a stylet like the one seen in Figure 2

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• v.9(4); 2011 Apr

Nematodes: The Worm and Its Relatives

Mark blaxter.

Institute of Evolutionary Biology, The University of Edinburgh, Ashworth Laboratories, Edinburgh, United Kingdom

Browse recently published articles in most issues of leading journals, and there will be mention of “the worm”. What is this worm, why is it so keenly studied by so many, and what has it told us about the diversity of life? And why this worm, and not one of the many other worms?

Caenorhabditis elegans Is the Worm

The worm is Caenorhabditis elegans , a small, bacteriovorous nematode (or roundworm) first described by Emile Maupas in 1900 [1] . While C. elegans had been known and studied in the laboratories of nematologists for many years, it was not until Sydney Brenner in Cambridge, United Kingdom, selected this species for his new programme in genetic research [2] , [3] that it became a global phenomenon. He wanted a species that was easy to keep, that had tractable genetics (so that mutants could be isolated and crosses made), and that was easy to observe. Brenner attracted a remarkable team of geneticists to join him, and C. elegans researchers have won three Nobel prizes for discoveries made using his new model organism.

So, why C. elegans ? One key feature of this nematode is how easy it has turned out to be to grow, observe, analyse, and manipulate (See Box 1 ). It thrives in simple petri-dish culture, and has a simple life cycle ( Figure 1 ). It is small, but easy to visualise under the microscope. It is see-through at all stages of development, facilitating the analysis of changes in development, or following experimental manipulation. C. elegans is an animal, and so has, like other animals, muscles, a nervous system, a digestive system, skin, and so on. Remarkably, and attractively, in C. elegans all these organs and tissues are built with very few cells: Brenner's postdoc John Sulston counted 558 nuclei in a hatching larva, and 959 in an adult hermaphrodite (excluding the germline) [4] – [6] . Sulston and colleagues mapped the origins and fates of all these nuclei during development in the beautifully transparent embryos. C. elegans embryos undergo a stereotypical pattern of cleavage from the just-fertilised zygote to the emerging first stage larva, such that (with a few important exceptions) the cell lineage is invariant [4] – [6] . For each cell in any embryo, it is possible to say with certainty where it came from (which cells in earlier embryos were its progenitors) and which cells (and tissues) the cell would contribute to the mature animal.

(A) C. elegans has a direct life cycle, with eggs developing through four larval stages into sexual adults. The larvae resemble the adults except in the lack of fully developed gonads, and their smaller size. The illustration shows the timing of developmental events at 25°C, with hours since fertilisation on the outside of the circle, and hours since hatching on the inside. Moults are indicated by solid black bars. In the hermaphrodite, the first ∼250 germ cells develop as sperm (after the L3 to L4 moult); later germ cells develop as oocytes. In conditions of overcrowding, starvation, or high temperature, C. elegans L1 commit to enter an alternate developmental pathway (via a lipid-storing alternate L2d) that results in the production of a diapausal dauer (“enduring”) L3d. The L3d is non-feeding, resistant to environmental insult, and displays arrested ageing. The L3d resumes development when exposed to sufficient food resources. Other nematodes also have a five-stage life cycle, punctuated by four moults, and many species, including parasites, also have a dauer-like L3 stage. (B) The adult hermaphrodite anatomy is simply observed under light microscopy. Above is an adult animal (length ∼1 mm). In the cartoon below the major organ systems are indicated.

Box 1. Setting Up to Study the Worm

There are many small animal species, yet C. elegans is the pre-eminent model. This is in part due to the ease of culture, manipulation, and observation of this nematode. Starting a lab to work on the worm requires, initially, only a few key tools: an incubator that maintains a ∼20°C environment, a good dissection microscope, and a good Internet connection. To observe developing embryos, an inverted Nomarski (differential interference contrast) compound microscope is sufficient.

• C. elegans does not need complex rearing conditions: it feeds on bacteria, and in the lab can be maintained at room temperature on agar plates covered with a lawn of the standard molecular biology bacterium Escherichicia coli . No bio-containment is required.
• It is small (adults are ∼1 mm in length), and thus millions of nematodes can be housed in a small space.
• It is transparent throughout the life cycle, making it easy to directly observe changes at the cellular level using standard live microscopy. This includes following the development of the embryo from fertilisation to hatching.
• It has a short life cycle, taking only 3 days to proceed from a fertilised egg to a sexual adult ( Figure 1 ). Thus, genetic experiments involving multiple generations can be completed in only a few days.
• Propagation is simple, as the standard sexual morph is the self-fertilising hermaphrodite. Because of this mode of reproduction, issues of inbreeding depression (where inbreeding results in lowered reproductive fitness of lines because of homozygous deleterious mutations) are largely absent. Matrilineal stocks can be propagated for decades.
• Genetic crossing is still possible, as C. elegans can also exist as fertile males that successfully mate with hermaphrodites to produce outcross offspring.
• C. elegans can be cryopreserved at −80°C, allowing strains to be archived securely.
• The C. elegans community has sponsored strain and genetic resources collections, and these are searchable online. Mutant strains can be ordered online, and delivered in days through standard mail.
• The genome sequence, and resources of transgenic strains and of RNA interference reagents targeting all the genes in the genome, make the process of identifying and detailing the genetic underpinnings of traits streamlined.

Many successful researchers have started their independent C. elegans labs by using these basic resources to perform imaginative screens for mutations affecting particular phenotypes of interest, and thus identifying new genes controlling key biological systems.

C. elegans “behaves” much as other animals do—finding food, finding mates, and avoiding danger. However, these behaviours are achieved with a tiny number of neurons: only 302 cell nuclei are present in the adult hermaphrodite nervous system. John White, Sydney Brenner, and colleagues used serial transmission electron microscopy to reconstruct the anatomy and, more importantly, connectivity of this simple nervous system in individual animals [7] . The neurons could be grouped into 118 classes, and their interactions through 7,600 synapses were identified. It remains the only animal nervous system with such a complete wiring diagram, but, frustratingly, it proved impossible to “compute” C. elegans behaviour from this, and thus the dynamic field of C. elegans neurobiology was founded.

From Locus to Gene to Genome

Brenner's first paper [3] described 619 visibly mutant strains picked from spontaneously arising variants and from cultures treated with the mutagen ethyl methanesulphonate. These were mapped and used to define six linkage groups, confirming the karyotype (2n = 12) and mode of sex determination (males have 2n = 11, and sex is determined by the number of X chromosomes). Importantly, these mutants include several that affect development, changing or deleting the fates of cells in the lineage. From these small, promising beginnings, a worldwide community of C. elegans researchers grew, using mutagenesis and careful developmental and biological analyses to reveal the genetic underpinnings of development, neurosensation, ageing, and many other phenotypes. The C. elegans research field has been openly collaborative from the beginning, with The Worm Breeder's Gazette an early example of open-access publishing of research findings by and to a self-defined community (see Table 1 ). One of the key products of this collaboration was the development of a genetic map, placing all the loci identified across the world on a common framework [8] .

Understanding the action of genes through their mutant phenotypes is revealing, but deeper insight can be won from the molecular nature of their gene products and the details of the lesions induced by mutation. To this end, research teams started using molecular biological tools to isolate the DNA for their genes and describing the biochemical and physiological functions. This process was aided by another community project, undertaken by John Sulston, Alan Coulson, and colleagues, of the generation of a physical map of the C. elegans genome [9] , [10] . Using a DNA fingerprinting technique, long, contiguous stretches of the chromosomes were assembled from overlapping cosmid clones. As these clones were further analysed, and the marker loci used in genetic mapping were cloned and placed on the physical map, it became ever easier to “clone your gene” from these mapped cosmids.

In the late 1980s, the nascent human genome sequencing program was looking for test beds for technologies to tackle the 3-gigabase human genome. The C. elegans genome had been sized at 100 megabases (Mb) [11] , and the physical map of overlapping cosmids was ideally suited to the DNA sequencing technologies available. Thus the C. elegans genome project was born. In a few short years, the high-quality genome sequence emerging from teams in Cambridge, UK (later at the Sanger Institute), and St. Louis, United States, revolutionised the way C. elegans researchers did their science [12] . The publication of the near-complete sequence in 1998 [13] meant that C. elegans was the first animal for which the genome was known. The availability of this sequence changed the ways in which the worm could be approached experimentally, and large-scale projects examining gene expression, gene knockout phenotypes, and genetic interactions joined the roster of single-gene, focussed projects. For the human genome project, the C. elegans genome consortium proved that dedicated teams, using a clone-by-clone sequencing strategy and the new assembly and analysis tools they developed, could indeed tackle large genomes. Many technologies first developed and used for the C. elegans genome, such as fingerprint mapping of large insert clones, using yeast artificial chromosome cloning systems, and the first generation of automated gene finders, have subsequently been used widely.

The C. elegans Toolkit

C. elegans has proved to be an excellent model research organism. It is not only easy to grow and study under the microscope, but it also is uniquely amenable to many genetic and other manipulations. Its transparency enables direct screening for defects and changes under the microscope, and technologies such as laser ablation (where individual nuclei are killed by the action of a laser directed through the objective of a microscope), and cell-specific optogenetic manipulation (where light-responsive ion channels and enzymes can be specifically induced in a single or a few cells) are key tools for cell-level investigation of neural and developmental systems. C. elegans can be genetically transformed by microinjection of foreign DNA, allowing transgenic analysis of gene function [14] , [15] . The use of green fluorescent protein as a transgenic marker was pioneered in C. elegans [16] . The phenomenon of RNA interference (RNAi; where double-stranded RNA applied to the organism specifically knocks down expression of the targeted gene) was first discovered and applied in C. elegans [17] . C. elegans has proved to be uniquely susceptible to RNAi: genes can robustly be knocked down by feeding nematode cultures on Escherichicia coli that express double-stranded RNA from the gene of interest. The simplicity of this method means that RNAi “feeding” libraries targeting all of the genes in the genome are available for use in screening [18] . C. elegans can be grown in bulk liquid culture and phenotyped, sorted, and counted automatically for high-throughput screening of drugs and other treatments.

“Four-dimensional” microscopy, tracking cells in space and time through development, can be used to define the effects of developmental mutants in a tiny fraction of the time taken by Sulston and colleagues to determine the wild-type lineage [19] , [20] . The small genome size and high quality of the sequence (it remains to this day the only absolutely complete animal genome) has in turn enabled all sorts of whole-genome assays. Thus, the model organism Encyclopaedia of DNA Elements (modENCODE) teams have used the full battery of next generation analysis tools (microarrays, DNA methylation analyses, deep sequencing transcriptomics, immunoprecipitation of chromatin bound to transcription factors) to define the regulation of the C. elegans genome through development [21] , [22] . All of these global surveys, and the many thousands of single-gene and single-system analyses, are collated and cross-referenced in the openly accessible online database WormBase [23] (see Table 1 for C. elegans and other data resources).

The simple and accessible nervous system has permitted analysis of many aspects of nervous system development and function of wide importance, including issues such as how neural cells take on specific fates [24] , how growing axons find their way and make the correct connections, and how individual neurons integrate the many inputs they experience. While C. elegans has very few sensory neurons (the sensory nervous system includes only 39 sensory neurons, most concentrated in the anterior amphids and labial sensillae [7] ), the genome sequence surprisingly revealed over 1,200 putative G-protein-coupled transmembrane receptors likely to be involved in sensing the environment. Multiple receptors are expressed in a single neuron, and generation of appropriate responses involves intra- and inter-cellular regulation. The nervous system in C. elegans , as in other organisms, is closely integrated with hormonal control of physiology, including the regulation of dauer entry and exit, fat storage, body size, and longevity [25] .

C. elegans Is a Model Animal

The pattern of development observed in C. elegans is markedly different from that seen in other well-studied organisms such as fruit flies or mammals. In flies and mammals, deleting one or a few cells from an embryo usually has no effect on subsequent development: the embryos regulate to replace the structures that would have been produced by the missing cells. In C. elegans , however, removal of cells from the embryo is like removing tiles from a mosaic: the other cells cannot change fates to replace the missing parts. Does this mean that work on C. elegans is merely the study of a curiosity of little wider relevance? Mosaic development is actually common in small non-vertebrates, and may be an adaptation to the need for rapid, reliable embryogenesis [26] , so C. elegans' developmental mechanisms are derived from regulative ancestors. Indeed, in the C. elegans embryo, the near-invariant pattern of the cell lineage is in fact set up by a series of complex cell–cell interactions. Importantly, this means that the processes and genetic circuits underpinning C. elegans development are likely to be common to all animals, and thus work on this simpler model has informed human and other research, and has had a huge impact on medical science.

The importance of C. elegans for the study of human biology has two facets. One is the startling finding that many of the genes in the C. elegans genome have close homologues in the human, and that many human disease genes are present in the worm. The simplicity of the nematode system makes it a favoured test bed for investigation of the function and interactions of these genes in biological systems affected in disease, including syndromes such as ageing and obesity. The second is the ability to ask simple, direct questions of the C. elegans system and thus get simple, direct answers of universal significance.

For example, Robert Horvitz, Paul Sternberg, and colleagues showed that the cell–cell and intracellular signalling pathways involved in the production of the hermaphrodite vulva (a process that takes place in the L3 and L4 stages) are common to all animals, and are also involved in embryogenesis and cancer in humans [27] . Horvitz and colleagues also were the first to define the pathway that controlled the programmed death (apoptosis) of specific cells during C. elegans embryogenesis [28] : this pathway is also found in humans, where it is an important regulator of cancerous growth.

As outlined above, RNAi was defined in C. elegans , and the phenomenon of RNAi is now known to use systems that are involved in innate immunity to viruses in humans and other organisms. Excitingly, genes encoding endogenous small RNAs, similar to the effector RNAs active in RNAi, were found in C. elegans through standard genetic screens investigating developmental mutants [29] . These defined the now burgeoning field of microRNAs (miRNAs), regulatory effectors critical in development and disease in humans, other animals, and plants.

Lastly, the dauer L3 is a non-ageing stage, and the genes that control entry and exit from the dauer were shown to affect the life span of C. elegans , even when they did not passage through dauer [30] . This ageing pathway is also effective in other animals, and analysis of Methuselah-like C. elegans mutants that live twice as long as wild type has implicated other deeply conserved pathways such as those of insulin signalling. These pathways are also implicated in ageing in other species, including humans.

C. elegans in the Wild

In the laboratory, C. elegans grows and thrives in a two-dimensional world of agar plates, and copious food in the form of E. coli . Obviously, this is an artificial environment. C. elegans is often introduced as a “soil nematode” but it is very rarely isolated from soils. The reference strain used since Brenner's pioneer experiments is “N2”, established from spent mushroom compost [31] , and most isolations have been from organic-rich environments such as urban compost heaps. However, while compost heaps are wilder than agar plates, they are still artificial environments constructed by humans. Where do C. elegans live when not living on human-concentrated rotting vegetation, or being cosseted on agar plates? A worldwide search for C. elegans by Marie-Anne Félix, Asher Cutter, and their colleagues has identified rotting fruits in temperate regions as a likely true wild habitat for this species [32] – [36] .

This discovery has made the task of collecting wild C. elegans a much more reliable pursuit, but raises new questions. How does C. elegans get to rotting fruit? What does the species do outside the fruiting season? The answers to these questions are still being worked out, but it is likely that the dauer L3 plays a key role. The dauer is an arrested form, and dauers can be harvested from the soils around rotting fruits: it is likely that they persist in the environment until the next food source drops from the tree. Dauers of Caenorhabditis species are also often found attached to the outsides of insects, woodlice, and millipedes. These arthropod species probably act as transport hosts for the nematodes, carrying them from one food source to another. C. elegans has been isolated from temperate sites worldwide, from Australia to Africa, and Canada to Asia [32] , [37] . The isolates have usually been from locations constructed by human action (e.g., compost heaps), and it is thus likely that the nematodes have been spread also by human action. Global transport of rooted plants and fruit, and wholesale transfer of soils, will also have efficiently carried C. elegans . As would be expected from this model, there is little global differentiation across C. elegans populations. Using highly variable microsatellite genetic markers, no evidence of isolation by distance was found, and small local areas contained as much genetic diversity as different continents. In this, C. elegans resembles the other key non-vertebrate model organism, the fruit fly Drosophila melanogaster . D. melanogaster , another lover of rotting fruit, has also been recently dispersed by human action from its origins in West Africa, and these diaspora populations show low levels of genetic distinction.

Interestingly, the “wild type” reference C. elegans , Brenner's N2 strain, is actually a multiple mutant, selected for growth in artificial lab conditions, and it may not be representative of most truly “wild” C. elegans . Wild males secrete a mucus plug over the hermaphrodite vulva during mating [38] , but N2 does not plug, due to a recent loss-of-function mutation [39] . N2 nematodes range widely on the agar plates seeded with E. coli , leaving the bacterial lawn frequently, but most wild strains do not leave the bacterial lawns, clumping wherever the bacterial growth is thickest. This difference is due to another recent reduction-in-function mutation in N2 in a neuropeptide receptor gene [40] , [41] .

Not All Nematodes Are C. elegans

When “traps” are laid to catch C. elegans , most of the nematodes that are caught are not the chosen worm. There are many bacteriovorous and fungivorous nematodes in soil and compost attracted to the rotting baits. Some of these are other Caenorhabditis species, such as the C. briggsae that Brenner initially worked on [34] . There are now about 25 known species in the genus Caenorhabditis [37] , [42] , [43] and many of these have been developed as satellite models to the main project. Using these species, it is possible to examine how the specific traits and genomic architectures of C. elegans came to be as they are, and thus develop predictive models of evolution. Species from other relatively closely related genera such as Pristionchus [44] , [45] and Oscheius [46] have also been used as alternate models.

Caenorhabditis is part of a diverse radiation of terrestrial nematodes, the Rhabditina. The Rhabditina includes not only free-living species such as C. elegans , but also nematodes that associate with insects and other arthropods, and species that are important animal parasites. The free-living rhabditids are important members of terrestrial ecosystems, part of the ecological webs that drive soil productivity. The arthropod-associated species include those that just use their hosts for transport, and several that are pathogens or parasites of insects. Some of the insect-pathogenic nematodes have been developed as safe biocontrol agents for crop pests, and can be purchased (as arrested dauer stages) from garden stores. The Rhabditina also includes a very important group of vertebrate parasites, the Strongyloidea. Strongyloids such as the human hookworm Necator americanus are important determinants of human health in tropical countries [47] , [48] , and major efforts are underway to develop new drugs and vaccines for the devastating diseases they cause. In these efforts, C. elegans research plays a major role, acting as a test bed for drugs, and an archetype onto which the specific details of parasite biology can be mapped. For example, the infective stage in Strongyloids is a dauer-like L3, and discovery of drugs that prevent dauer exit, or mis-specify post-dauer development, may have important roles in community control programmes. Many agricultural animals are also susceptible to infection by a range of strongyloid species, and again C. elegans is used in preliminary studies for veterinary drug development.

The Phylum Nematoda

Rhabditina is only one small part of the diversity of the phylum Nematoda. Nematodes are very diverse, not only in morphology (despite a general perception that nematodes are boring, they in fact have lots of morphological diversity), but also in size (adults from less than a millimetre to over 6 metres), life cycles (from parthenogens to complex cycles of alternating sexual strategies), and ecology (including parasites of almost all other large multicellular organisms, plant and animal). While only about 23,000 species have been described, current estimates suggest that there may be over a million nematode species on Earth [49] . Most species are members of the meiofauna that lives in marine sediments, where nematodes outnumber all other animals many fold [50] . Nathan Cobb, a pioneer nematologist, asked his readers to imagine a world where everything except the nematodes had been magically taken away: “our world would still be dimly recognizable…we should find its mountains, hills, vales, rivers, lakes, and oceans represented by a film of nematodes” [51] .

Understanding of the phylogenetic relationships of nematodes has been changed by the use of DNA sequence data [52] – [54] . The new view of phylum Nematoda ( Figure 2 ) [55] , [56] shows three major branches, the Enoplia, Dorylaimia, and Chromadoria. C. elegans is placed in the Chromadoria, along with the Tylenchina (a group that includes important plant parasites, including many that devastate crops worldwide, such as Meloidogyne incognita , a species that can parasitise a surprisingly wide range of hosts, as well as free-living and animal parasitic species), Spirurina (which are all animal parasites, including those causing human filariases—river blindness [ Onchocerca volvulus ] and elephantiasis [ Brugia malayi ]), and other Rhabditina. In the Dorylaimia are terrestrial predatory species that play key roles in food webs, and insect and animal parasites. One of these dorylaim parasites is Trichinella spiralis , the trichina worm, a fascinating species that can infect many vertebrates and non-vertebrates, and causes a nasty disease in humans when diapausing larvae (the L1 stage in this case) are ingested in uncooked meats, usually pig or wild meats such as bear. The Enoplia are mainly marine, and include microbivores, predators, and a group of terrestrial herbivores (or plant parasites), the Trichodoridae. Trichodorids such as Xiphinema index affect their plant hosts by both feeding on the roots, and through specific transmission of devastating viruses. Parasitism of animals and plants has arisen multiple times in the Nematoda, and convergent evolution in other traits is also common [56] – [58] .

This phylogeny is based on molecular phylogenetic analyses utilising the small subunit ribosomal RNA gene. The systematic names given by De Ley and Blaxter [55] , [56] are given, as is the “clade” naming convention introduced by Blaxter et al. in 1998 [52] . More recently, Helder and colleagues [53] , [77] have introduced a numerical clade name scheme: this is given in outlined letters below the relevant branches. Feeding mode, and animal and plant parasitic and vector associations, are indicated by small icons, and representative species are named for some groups. Species with a sequenced genome are indicated by an asterisk.

One of the important results to emerge from the comparison to other nematodes is that the extreme mosaicism seen in C. elegans development is not found in all species [59] – [62] . Mosaic development in C. elegans , and related nematodes in the Chromadoria, is a derived trait. These and other comparisons are contextualising the details of the C. elegans project, as well as pointing out where this model nematode has followed a very idiosyncratic evolutionary path.

Nematode Genome Projects

Research on the huge number of other nematode species does not approach that on C. elegans in its depth or detail, but there are especially large literatures on the human parasites and the diseases they cause. One way in which the diversity of nematodes has been approached is through comparative genomics. Initially, this was achieved through directed sequencing of the expressed genes of the target species (the transcriptome approach). Over 60 transcriptome datasets have been generated for free-living, animal-parasitic, and plant-parasitic species [63] . Furthermore, using the C. elegans genome project as a methodological and biological guide, teams have developed complete genome sequences for plant parasites ( M. incognita [64] and Meloidogyne hapla [65] ) and animal parasites ( B. malayi [66] and T. spiralis [67] , [68] ), as well as additional free-living species ( Pristionchus pacificus [69] , [70] and additional Caenorhabditis species [71] ). The C. elegans genome, at 100 Mb, is small compared to that of humans (which is 30 times bigger), but appears to be about standard for nematodes (the other sequenced species genomes range from 50 Mb to 120 Mb). The advent of new sequencing technologies has spurred a major increase in the scale of nematode genomics, and nearly a hundred genome projects are under way or planned [72] . These new genomes will reveal not only the special biology of the individual species they represent, but also expand the reach and universality of the ongoing C. elegans programme.

Putting the Worm on the Tree of Life

Molecular data have also clarified the position of Nematoda in relation to other animals. Before the late 1990s, nematodes, along with a rag-bag of other soft-bodied, “wormy” phyla, had been placed in a group termed the Pseudocoelomata (describing the nature of the body cavity in these taxa). However, the morphological arguments supporting this superphylum were never strong, and despite the absolute certainty expressed in textbook treatments of the phylogeny of the animals, leaders in the field, such as Libby Hyman, always expressed grave doubts as to the biological reality of this grouping [73] . Analysis of ribosomal RNA sequence data from a range of nematodes, however, suggested instead a radical rearrangement of the animal part of the tree of life [74] . In this new model, which has strong support from several genes and some support from morphological data, Nematoda is part of a superphylum of moulting animals, the Ecdysozoa [74] , that includes Arthropods (and thus D. melanogaster , the other major non-vertebrate model), Nematomorpha (horsehair worms ), Onychophora (velvet worms ), Tardigrada (water bears), Priapulida (penis worms ), and other minor phyla. The rest of the “pseudocoelomates” are now placed in the Lophotrochozoa [75] , [76] , a group that includes Mollusca (snails and clams), Annelida (rag worms and earth worms ), and Platyhelminthes (flat worms ), amongst others.

Thus, the worm is only one nematode of many, and nematodes are only one sort of worm. Despite this, C. elegans is still a model organism par excellence : it is a good model nematode, and a good model animal, and a good model for the basic biology that underpins all life.

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• 2. Multiple Choice Edit 30 seconds 1 pt which species of nematode is transferred to humans by eating infected pig meat trichonella pinworm diroflaria cestoda

collection of nerve cells located at the anterior end of a worm

cephalization

grasping mouth parts

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used for movement in nematodes

grasping mouthparts

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Roundworms can be transmitted by

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swimming in dirty water

walking barefoot around feces

Roundworms have a false body cavity called

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Cannibalism and genome duplication in nematodes

by Max Planck Society

Researchers at the Max Planck Institute for Biology have produced intriguing evidence of how environmental factors and genetic adaptation can lead to the evolution of novel and aggressive traits and behaviors in nematodes.

The discovery of genome duplication and a new cannibalistic morph in Allodiplogaster sudhausi raises questions about how these genetic changes impact social dynamics , intra-species interactions and resource competition within nematode populations. Their findings are reported in Science Advances .

One of the most perplexing mysteries in evolutionary biology is the development of complex traits that often results in morphological diversity. Prof. Dr. Ralf Sommer, Director of the Department of Integrative Evolutionary Biology, has dedicated his life's work to the role of the environment in the development of plasticity and epigenetics.

This research continues to provide evidence of plasticity's profound effect and importance on the morphology, physiological, or behavioral changes in organisms throughout generations.

Nematodes are microscopic roundworms found in the soil. They usually feed on bacteria and are microscopic. Sommer's team researched the nematode Allodiplogaster sudhausi. The new study reveals a surprising twist: These creatures can evolve a giant mouth, develop cannibalistic behavior and they grow twice the size of most soil nematodes.

Stressful and low nutritional conditions induce cannibalism

Prior research on A. sudhausi indicated the presence of two distinct feeding morphotypes that differ in the shape of the mouth and complexity of the teeth. However, Sara Wighard, lead author and former doctoral researcher, identified a surprising third morph.

When fed various fungi, including Penicillium camemberti, the worm developed a gigantic mouth, later called a Terastostomatous (Te) morph. These Te worms were also found under stressful conditions of starvation and crowding. Strikingly, this newly identified morph displayed never-before-seen cannibalistic behavior, where they predate on their own kin despite being genetically identical (these worms are hermaphroditic and don't require males to make offspring).

Sommer explains what could cause them to cannibalize their kin, "They don't receive enough nutrients from the fungi, and along with the resource pressure of being surrounded with so many other worms, they turned more aggressive in response to stress." Outside a lab setting, the cannibalistic behavior would give the species a greater chance of long-term survival in stressful conditions.

Previous findings of Wighard revealed that this species underwent a whole genome duplication (WGD). Unlike their 1-millimeter-long relatives, A. sudhausi grew to 2 millimeters due to WGD, making them visible to the naked eye.

Tracking the novel morph formation

Since the novel trait of a third mouth morph displays no overlap with the other two known morphs, the researchers set out to identify the mechanism regulating the new morph. Using CRISPR, they found conserved developmental switch genes regulates the emergence of this third mouth morph, indicating the co-option of existing genetic mechanisms. Gene dosage studies then revealed the distinct roles of these developmental switches in determining different mouth-forms.

The correlation implies that large-scale genomic alterations like WGD may drive nematodes' morphological novelties and phenotypic diversity. Since no other strain shows similar changes, the team is limited in identifying this phylogenetic resolution until further research is conducted.

Overall, the study sheds light on the complex interplay between environmental factors , in this case, diet and crowding, and genetic changes in shaping morphological diversity. The finding of a new mouth morph with cannibalistic behavior and the WGD event further supports the importance of developmental plasticity in influencing the species' evolutionary path.

This discovery suggests that nematodes can rapidly adapt to harsh environments by developing new traits like cannibalism. The ability to change based on environmental pressures could be crucial to their long-term survival.

Journal information: Science Advances

Provided by Max Planck Society

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Apples are the only thing that can save me from over-eating

As i walk the road to clean eating, apples have joined me. they may actually be my strongest ally, by d. watkins.

A few apples a day can keep the guilt away . . . or whatever mom used to say. 

I don't want to act like I have discovered a foolproof plan, and no, you will not shed an " Ozempic  amount" of pounds by following me; however, I have found a natural way to curb your appetite while still being able to enjoy some of your favorite foods in moderation. 

I love food and I know this is something that we expect all hungry and greedy people like me to say, but my story goes deeper. There's something extremely satisfying about that first bite into a burger with the perfect temperature, buttery golden eggs fried just right, or that last slice of cheesy, greasy pizza. I could literally go out to eat at a restaurant every day of the week if it weren't so expensive.

Having this kind of appetite is not sustainable, though, especially if you want to avoid being stretched across the hospital bed with a blood pressure of 300 over 200. So, what do we do?

Many people feel like the answer is forcing yourself to love unseasoned salmon and lettuce for your three meals a day. And sure, you may be able to get through a week or so, but you will get so bored that I guarantee you'll run right back towards that greasy pizza — and there's nothing wrong with that, outside of forgetting the reason why you tried clean eating in the first place.

Food is good and we deserve delicious meals just like we deserve to be healthy; I think this can be done in moderation. I had this conversation with my mother, who is also on a health journey. 

For context, my mother is pretty healthy for a woman in her early 60s. She moves around well, takes long walks when the weather is nice and is relatively small — she can even fit into her clothes from decades ago.

We need your help to stay independent

"Hey, what's your secret, ma?" I asked, complimenting her size, during our last extensive food conversation. 

She gave me a long, dense answer, talking about fiber and bowel movements, and yes, I'm going to spare you. Not because I black out and instantly transform into an immature child anytime a person starts talking about feces, but apples. Apples was her point and the answer. 

"I don't have a datasheet or publishable statistics, but I noticed that I didn't eat as much during the first week. "

My mother's secret is apples . She started eating two or three apples daily and was less hungry and maintained the same amount of energy, if not more. 

So, I tested her theory. I don't have a data sheet or publishable statistics, but I noticed that I didn't eat as much during the first week. My wife and I have been notorious for eating dinner at 9:00 and 10:00 at night, but on the days I've had two or more apples, I found it very easy to wait until the next day. Knowing this, I decided to start eating an apple with every meal. It doesn't matter if I'm eating something healthy like that unseasoned salmon or that pasta dish that is deserved after having long weeks — I always started with one apple. 

I have been doing this for about two weeks now and notice that I cannot eat as much. Yes, I can have steak frites and pizza and whatever, but if I have an apple first, I will only be eating a portion of my main course. If I eat that apple first, I won't be demolishing a whole burger — only half (and maybe a few fries.) 

Want more great food writing and recipes? Subscribe to Salon Food's newsletter , The Bite.

The beauty of this is that the apples are easy to carry around as I keep a bowl in my house and a bag with three or four of them in the car. So even when I'm mobile and have to eat on the run, I always have an apple available. You can do this with celery, cucumbers and other vegetables, too. 

I challenge you to eat an apple or a few pieces of celery before you eat that burger and I guarantee it will be harder to finish. Dessert may not even be an option! Now that's moderation. 

I understand that this may not be the most practical thing in the world to try, but I loaded up on apples and I'm going to continue this journey because I'm eating a lot less, still enjoying the food that I love and I feel great.

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D. Watkins is an Editor at Large for Salon. He is also a writer on the HBO limited series "We Own This City" and a professor at the University of Baltimore. Watkins is the author of the award-winning, New York Times best-selling memoirs “ The Beast Side: Living  (and Dying) While Black in America ”, " The Cook Up: A Crack Rock Memoir ," " Where Tomorrows Aren't Promised: A Memoir of Survival and Hope " as well as " We Speak For Ourselves: How Woke Culture Prohibits Progress ." His new books, " Black Boy Smile: A Memoir in Moments ," and " The Wire: A Complete Visual History " are out now.

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