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Tag: invertebrate

  • Why Do Octopuses Have Such a Large Brain?

    Why Do Octopuses Have Such a Large Brain?

    The startling similarity between us vertebrates and the invertebrate octopus is that little snippets of RNA may play a critical role in the formation of huge brains. This is due to the fact that octopuses’ nerve tissue and brains contain more active microRNAs than those of any other invertebrate.


    Indeed, their collection of these proteins is the third greatest in all of life. This may be the key to understanding the extraordinary intelligence shown by these cephalopods.

    No other animal group has the same genetic structure as the octopus, and no other invertebrate has developed such a sophisticated neurological system or as much intellect. Sea creatures like the octopus, squid, and cuttlefish have remarkable cognitive abilities. They are numerate and handy with tools. Octopuses have more neurons and neurological connections than rats and canines, respectively.

    Typical of squid like this young octopus
    Typical of squid like this young octopus, they have enormous lenticular eyes, a massive brain, and a complicated neurological system.

    Utilizing miRNAs as a Target

    But why squid have developed such enormous, sophisticated brains, and how, is still only partly known. Researchers headed by Grygoriy Zolotarov of the Max Delbrück Center have therefore explored a particularly specific component of the cell biology of the sick: microRNA. Unlike messenger RNA, which contains genetic instructions for making proteins, these RNA fragments do not. However, they can bind to this mRNA and control how much of its information is translated into proteins.

    Researchers Zolotarov and colleagues examined miRNA expression in 18 tissues from O. vulgaris, the common octopus, and O. bimaculatus, the California two-spotted octopus. What this showed was that there was something remarkable going on in the octopus tissues, where over 138 different families of microRNAs were all actively working. In addition, 90 of these microRNA families were previously unknown.

    The number of microRNAs in the neural tissue of an octopus is higher than that of any other invertebrate.

    MiRNA Repertoire Growth Is Exponential

    After that, they compared the octopuses’ microRNA repertoire to that of the primordial, low-intelligence mollusk Nautilus and the dwarf squid Euprymna scolopes. The researchers report discovering 90 novel microRNA families, 12 of which were also present in Nautilus and the dwarf squid, and are therefore representative of the core cephalopod repertoire. 35 microRNA families were solely found in octopuses, whereas 43 were present only in octopuses and dwarf squid.

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    The research found that the amount of microRNAs has expanded drastically throughout the history of evolution, from primitive cephalopods like Nautilus to complex, high-functioning squid with a massive brain. This is the biggest microRNA family growth outside of vertebrates, and the third largest in the animal world overall. No other invertebrate animal has such a vast amount of microRNAs.

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    Squid, which are classified as invertebrates like chickens, actually contain more microRNA families (138 in all) than chickens do.

    Active Primarily in Brain and Nerve Tissue

    This leads scientists to wonder whether the octopuses’ huge brains and extraordinary intellect have anything to do with the remarkable growth of their microRNA repertoire. To elucidate this, Zolotarov and coworkers looked at the octopuses’ microRNAs and where they are active. Of the 43 octopus-specific miRNAs examined, 34 were determined to be functional in nervous system tissues. The average expression level in neural tissues was 13-fold higher than in other types of tissue.

    Accordingly, microRNAs very certainly serve an important function in the maturation of brain and neural tissue. Researchers conclude that the rapid expansion of the squid’s microRNA repertoire supports the idea that microRNAs and the specific neuronal processes they regulate are important to the formation of sophisticated animal brains.

  • How Come Earthworm Can Still Live After Splitting In Half?

    How Come Earthworm Can Still Live After Splitting In Half?

    Earthworms are disliked by a large number of humans, and birds like eating them since when it rains, they will often abandon their underground habitat. The common earthworm is known in Latin by the name Lumbricus terrestris. These animals have strange characteristics that many people witnessed as children: You can slice through the worm with a pointed shovel, but both ends of the earthworm’s body will continue to move around. The worm has the ability to recreate the lost part of its body entirely. But how does this even happen in the first place?

    The Location of the Cut Matters

    How come earthworm can still live after splitting in half?
    (Credit: Addison Wesley Longman)

    Even though it is missing a significant portion of its body, the worm is nonetheless able to live on. The earthworm has the ability to regenerate the lost section of its body. However, it seems to make a difference where on the worm the cut was made.


    Only the front portion that contains the mouthparts can be regenerated, and this can only happen if only a few segments are lost. The head of the worm is where the digestive system and the central brain are found.

    Surviving Without A Head

    Yet, it is still possible to encounter surviving rear ends that do not have a head. Due to the fact that a worm without its head is unable to eat effectively, it can only have a short lifespan in this scenario. This rare phenomenon happens as a result of both ends being genuinely capable of regeneration. However, the rear end can only give birth to another rear end; hence, all of the vital organs that are located in the front section are lost. The front end, on the other hand, has the capability of regenerating a new rear end and creating a whole worm in this way.

    Still, there is a low chance that these damaged worms will be able to live in the wild because of infections in their wounds.

    How Does An Earthworm Regenerate Its Missing Part?

    It is known that approximately a week is required for the worm to develop its missing body section. During this period of time, a wound layer will begin to develop on the end. Cells from the gut and the skin move into the damaged area to begin the process of progressively forming the new body segments.


    The segments on the rear end regenerate quicker than those on the front. Additionally, the rear replacements are narrower, at least at the beginning of the regeneration.

    It takes about two to three months for the pigmentation of new segments to return to the worm’s true color.

    How Earthworm Still Moves After Being Cut Off

    The separated ends of an earthworm’s body may appear to crawl around so deftly. This phenomenon has a biological cause as well: Earthworms have what is referred to as a “ladder-like” nervous system, which, as the name implies, goes through the whole body similar to a rope ladder. The pain causes the earthworm’s flight instinct to be activated, and it does so whether the worm is only squeezed or entirely cut. This response causes muscular twitching, which is why the earthworm appears to crawl around after being cut. However, if the shovel strikes the earthworm in the wrong spot, the animal may not regenerate from it.