30.10.2019
Unpaired fins of fish. Biology at the Lyceum. Fish fins: shape, structure
TOPIC 1.
Fish fins Organi dihannya, zoru that hearing.
FISH FINS
Fins are a characteristic feature of the structure of fish. They are divided into paired, corresponding to the limbs of higher vertebrates, and unpaired, or vertical.
Paired fins include pectoral and ventral fins. Unpaired ones consist of a dorsal (one to three), caudal and anal (one or two). Salmon, grayling and other fish have an adipose fin on their back, and mackerel, tuna, and saury have small additional fins behind the dorsal and anal fins. The position of the fins on the body, their shape, size, structure and functions are very diverse. Fish use fins to move, maneuver and maintain balance. The caudal fin plays the main role in moving forward in most fish. It performs the work of the most advanced propeller with rotating blades and stabilizes the movement. The dorsal and anal fins are a kind of keels for giving the fish’s body the desired stable position.
Two sets of paired fins serve for balance, braking and steering.
The pectoral fins are usually located behind the gill openings. The shape of the pectoral fins is related to the shape of the caudal fins: they are rounded in fish that have a rounded tail. Good swimmers have pointed pectoral fins. The pectoral fins of flying fish are especially strongly developed. Thanks to the high speed of movement and the blows of the caudal fin, flying fish jump out of the water and soar on their wing-like pectoral fins, covering a distance of up to 100-150 m in the air. Such flights help them hide from the pursuit of predators.
The pectoral fins of the monkfish have a jointed, fleshy base. Relying on them, the monkfish moves along the bottom in leaps and bounds, as if on its feet.
The location of the pelvic fins varies from fish to fish. In lowly organized fish (sharks, herring, carp) they are located on the belly. In more highly organized fish, the ventral fins move forward, occupying a position under the pectoral fins (perch, mackerel, mullet). In cod fish, the pelvic fins are located in front of the pectoral fins.
In gobies, the pelvic fins are fused into a funnel-shaped sucker.
The pelvic fins of the lumpfish have changed into an even more amazing adaptation. Their suction cup holds the fish so firmly that it is difficult to tear it off the stone.
Of the unpaired fins, the caudal one deserves special attention, the complete absence of which is very rarely observed (stingrays). Based on the shape and location relative to the end of the spine, several types of caudal fins are distinguished: asymmetrical (heterocercal) - in sharks, sturgeons, etc.; falsely symmetrical (homocercal) - in most bony fish.
The shape of the caudal fin is closely related to the fish's lifestyle and especially its ability to swim. Good swimmers are fish with lunate, fork-shaped and notched tails. Less mobile fish have a truncated, rounded caudal fin. In sailboats it is very large (up to 1.5 m long), they use it as a sail, placing it above the surface of the water. In spiny-finned fish, the rays of the dorsal fin are strong spines, often equipped with poisonous glands.
A peculiar transformation is observed in the sticky fish. Its dorsal fin moves to its head and turns into a suction disk, with the help of which it attaches to sharks, whales, and ships. In angler fish, the dorsal fin moves to the snout and extends into a long thread that serves as a bait for prey.
All fins in fish are divided into paired, which correspond to the limbs of higher vertebrates, and unpaired. Paired fins include pectoral (P - pinna pectoralis) and ventral (V - pinna ventralis). Unpaired fins include dorsal (D - p. dorsalis); anal (A - p. analis) and tail (C - p. caudalis).
A number of fish (salmonids, characins, killer whales, etc.) have an adipose fin behind the dorsal fin; it lacks fin rays (p.adiposa).
Pectoral fins are common in bony fishes, while they are absent in moray eels and some others. Lampreys and hagfish are completely devoid of pectoral and ventral fins. In stingrays, the pectoral fins are greatly enlarged and play the main role as organs of their movement. Especially strong pectoral fins have developed in flying fish. The three rays of the pectoral fin of the gurnard serve as legs when crawling on the ground.
The pelvic fins can occupy different positions. Abdominal position - they are located approximately in the middle of the abdomen (sharks, herring-shaped, carp-shaped). In the thoracic position, they are shifted to the front of the body (perch-shaped). Jugular position, fins located in front of the pectorals and on the throat (cod).
In some fish, the pelvic fins are transformed into spines (stickleback) or suckers (leaffish). In male sharks and rays, the posterior rays of the pelvic fins have been transformed into copulatory organs in the process of evolution. They are completely absent in eels, catfish, etc.
There may be a variable number of dorsal fins. In herring and cyprinids it is one, in mullet and perch morphs there are two, in cod morphs there are three. Their location may vary. In pike it is shifted far back, in herring and carp fish - in the middle of the body, in perch and cod - closer to the head. The longest and highest dorsal fin of the sailfish. In flounder, it looks like a long ribbon running along the entire back and, at the same time as the anal one, is their main organ of movement. Mackerel, tuna and saury have small additional fins behind the dorsal and anal fins.
Individual rays of the dorsal fin sometimes extend into long threads, and monkfish the first ray of the dorsal fin is shifted to the muzzle and transformed into a kind of fishing rod, like in deep sea anglerfish. The first dorsal fin of the sticky fish also moved to the head and turned into a real sucker. The dorsal fin in sedentary benthic fish species is weakly developed (catfish) or absent (rays, electric eel) .
Tail fin:
1) isobathic – the upper and lower blades are the same (tuna, mackerel);
2) hypobate – the lower lobe is elongated (flying fish);
3) epibate – the upper lobe is elongated (sharks, sturgeons).
Types of caudal fins: forked (herring), notched (salmon), truncated (cod), rounded (burbot, gobies), semilunate (tuna, mackerel), pointed (elpout).
From the very beginning, the fins have been assigned the function of movement and maintaining balance, but sometimes they also perform other functions. The main fins are dorsal, caudal, anal, two ventral and two pectoral. They are divided into unpaired - dorsal, anal and caudal, and paired - pectoral and abdominal. Some species also have an adipose fin located between the dorsal and caudal fins. All fins are driven by muscles. In many species, the fins are often modified. Thus, in male viviparous fish, the modified anal fin has turned into a mating organ; some species have well-developed pectoral fins, which allows the fish to jump out of the water. Gourami have special tentacles, which are thread-like pelvic fins. And some species that burrow into the ground often lack fins. Guppy tail fins are also an interesting creation of nature (there are about 15 species of them and their number is growing all the time). The movement of the fish begins with the tail and caudal fin, which with a strong blow send the body of the fish forward. The dorsal and anal fins provide balance to the body. The pectoral fins move the body of the fish during slow swimming, serve as a rudder, and, together with the pelvic and caudal fins, ensure the equilibrium position of the body when it is at rest. In addition, some species of fish can rely on pectoral fins or move with their help on hard surfaces. The pelvic fins perform mainly a balancing function, but in some species they are modified into a suction disc, which allows the fish to stick to a hard surface.
1. Dorsal fin.
2. Adipose fin.
3. Caudal fin.
4. Pectoral fin.
5. Pelvic fin.
6. Anal fin.
The structure of a fish. Types of tail fins: 
Truncated
Split
Lyre-shaped
24. Structure of fish skin. The structure of the main types of fish scales, their functions.
Fish skin performs a number of important functions. Located on the border between external and internal environment body, it protects the fish from external influences. At the same time, separating the fish body from the surrounding liquid environment with chemicals dissolved in it, the fish skin is an effective homeostatic mechanism.
Fish skin quickly regenerates. Through the skin, on the one hand, partial release of the final metabolic products occurs, and on the other, the absorption of certain substances from the external environment (oxygen, carbonic acid, water, sulfur, phosphorus, calcium and other elements that play a large role in life). The skin plays an important role as a receptor surface: thermo-, barochemo- and other receptors are located in it. In the thickness of the corium, the integumentary bones of the skull and pectoral fin girdles are formed.
In fish, the skin also performs a rather specific – supporting – function. Muscle fibers of skeletal muscles are attached to the inner side of the skin. Thus, it acts as a supporting element in the musculoskeletal system.
Fish skin consists of two layers: outer layer epithelial cells, or epidermis, and an inner layer of connective tissue cells - the skin itself, dermis, corium, cutis. Between them there is a basement membrane. The skin is underlain by a loose connective tissue layer (subcutaneous connective tissue, subcutaneous tissue). In many fish, fat is deposited in the subcutaneous tissue.
The epidermis of fish skin is represented by multilayer epithelium, consisting of 2–15 rows of cells. The cells of the upper layer of the epidermis are flat in shape. The lower (germ) layer is represented by one row of cylindrical cells, which, in turn, originate from the prismatic cells of the basement membrane. The middle layer of the epidermis consists of several rows of cells, the shape of which varies from cylindrical to flat.
The outermost layer of epithelial cells becomes keratinized, but unlike terrestrial vertebrates in fish, it does not die, maintaining contact with living cells. During the life of a fish, the intensity of keratinization of the epidermis does not remain unchanged; it reaches its greatest degree in some fish before spawning: for example, in male cyprinids and whitefishes, the so-called Pearly rash is a mass of small white bumps that make the skin feel rough. After spawning it disappears.
The dermis (cutis) consists of three layers: a thin upper (connective tissue), a thick middle mesh layer of collagen and elastin fibers and a thin basal layer of tall prismatic cells, giving rise to the two upper layers.
In active pelagic fish the dermis is well developed. Its thickness in areas of the body that provide intense movement (for example, on the caudal peduncle of a shark) is greatly increased. The middle layer of the dermis in active swimmers can be represented by several rows of strong collagen fibers, which are also connected to each other by transverse fibers.
In slow-swimming littoral and bottom-dwelling fish, the dermis is loose or generally underdeveloped. In fast-swimming fish, there is no subcutaneous tissue in the parts of the body that provide swimming (for example, the caudal peduncle). In these places, muscle fibers are attached to the dermis. In other fish (most often slow ones), the subcutaneous tissue is well developed.
The structure of fish scales:
Placoid (it is very ancient);
Ganoid;
Cycloid;
Ctenoid (youngest).
Placoid fish scales
Placoid fish scales(photo above) characteristic of modern and fossils cartilaginous fish- and these are sharks and rays. Each such scale has a plate and a spine sitting on it, the tip of which extends out through the epidermis. The basis of this scale is dentin. The spike itself is covered with even harder enamel. The placoid scale inside has a cavity that is filled with pulp - pulp, it has blood vessels and nerve endings.
Ganoid fish scales
Ganoid fish scales has the appearance of a rhombic plate and the scales are connected to each other, forming a dense shell on the fish. Each such scale consists of a very hard substance - the upper part is made of ganoine, and the lower part is made of bone. A large number of fossil fish have this type of scale, as well as the upper parts in the caudal fin of modern sturgeon.
Cycloid fish scales
Cycloid fish scales found in bony fish and does not have a ganoine layer.
Cycloid scales have a rounded neck with a smooth surface.
Ctenoid fish scales
Ctenoid fish scales also found in bony fish and does not have a layer of ganoine; it has spines on the back side. 
Usually the scales of these fish are arranged in a tiled manner, and each scale is covered in front and on both sides by the same scales. It turns out that the rear end of the scale comes out, but underneath it is lined with another scale and this type of cover preserves the flexibility and mobility of the fish. Annual rings on the scales of a fish allow one to determine its age.
The arrangement of scales on the body of a fish is in rows and the number of rows and the number of scales in a longitudinal row does not change with changes in the age of the fish, which is an important systematic feature for different types. Let's take this example - the lateral line of a golden crucian carp has 32-36 scales, while a pike has 111-148.
The habitat of fish is all kinds of bodies of water on our planet: ponds, lakes, rivers, seas and oceans.
Fish occupy very vast territories; in any case, the ocean area exceeds 70% of the earth's surface. Add to this the fact that the deepest depressions go 11 thousand meters into the ocean depths and it becomes clear what spaces the fish own.
Life in water is extremely diverse, which could not but affect the appearance of fish, and led to the fact that the shape of their bodies is varied, like underwater life itself.
On the head of fish there are gill wings, lips and mouth, nostrils and eyes. The head transitions into the body very smoothly. Starting from the gill wings to the anal fin there is a body that ends with a tail.
Fins serve as organs of movement for fish. In essence, they are skin outgrowths that rest on bony fin rays. The most important thing for fish is the caudal fin. On the sides of the body, in its lower part, there are paired ventral and pectoral fins, which correspond to the hind and forelimbs of vertebrates living on the earth. In different species of fish, paired fins can be located differently. At the top of the fish’s body there is a dorsal fin, and at the bottom, next to the tail, there is an anal fin. Moreover, it is important to note that the number of anal and dorsal fins in fish can vary.
Most fish have an organ on the sides of their body that senses the flow of water, called the “lateral line.” Thanks to this, even a blind fish is able to catch moving prey without bumping into obstacles. The visible part of the lateral line consists of scales with holes.
Through these holes, water penetrates into a channel running along the body, where it is sensed by the endings of nerve cells passing through the channel. The lateral line in fish can be continuous, intermittent, or absent altogether.
Functions of fins in fish
Thanks to the presence of fins, fish are able to move and maintain balance in the water. If the fish is deprived of fins, it will simply turn over with its belly up, since the center of gravity of the fish is located in its dorsal part.
The dorsal and anal fins provide the fish with a stable body position, and the caudal fin in almost all fish is a kind of propulsion device.
As for the paired fins (pelvic and pectoral), they mainly perform a stabilizing function, since they provide an equilibrium position of the body when the fish is immobilized. With the help of these fins, the fish can take the body position it needs. In addition, they are load-bearing planes during the movement of the fish, and act as a rudder. As for the pectoral fins, they are a kind of small motor with which the fish moves during slow swimming. The pelvic fins are primarily used to maintain balance.
Body shape of fish
Fish are characterized by a streamlined body shape. This is a consequence of her lifestyle and habitat. For example, those fish that are adapted to long and fast swimming in the water column (for example, salmon, cod, herring, mackerel or tuna) have a body shape similar to a torpedo. Predators that practice lightning-fast throws over very short distances (for example, saury, garfish, taimen or) have an arrow-shaped body shape.
Some species of fish that are adapted to a long stay on the bottom, such as flounder or stingray, have a flat body. Some types of fish even have bizarre body shapes, which can resemble a chess horse, as can be seen in, whose head is located perpendicular to the axis of the body.
The seahorse inhabits almost all sea waters on Earth. Its body, like an insect, is enclosed in a shell, its tail is tenacious like that of a monkey, its eyes are able to rotate like a chameleon, and completes the picture with a bag, like the one that a kangaroo has. And although this strange fish can swim, keeping the vertical position of the body, using the vibrations of the dorsal fin for this, the swimmer from it is still useless. The seahorse uses its tubular stigma as a “hunting pipette”: when prey is shown nearby, the seahorse sharply inflates its cheeks and draws the prey into its mouth from a distance of 3-4 centimeters.
The smallest fish is the Philippine goby Pandaku. Its length is about seven millimeters. It was even such that women of fashion wore this bull in their ears, using crystal aquarium earrings for this.
But the largest fish is, the body length of which is sometimes about fifteen meters.
Additional organs in fish
In some fish species, such as catfish or carp, antennae can be seen around the mouth. These organs perform a tactile function and are also used to determine taste qualities food. Many deep-sea fish such as photoblepharon, anchovy, and hatchet fish have luminous organs.
On the scales of fish you can sometimes find protective spines, which can be located in different parts of the body. For example, the body of a hedgehog fish is almost completely covered with spines. Certain fish species, such as the wartfish, sea Dragon and, have special organs of attack and defense - poisonous glands, which are located at the base of the fin rays and the base of the spines.
Body coverings in fish
On the outside, the skin of fish is covered with thin translucent plates - scales. The ends of the scales overlap each other, arranged like tiles. On the one hand, this provides the animal with strong protection, and on the other hand, it does not interfere with free movement in the water. The scales are formed by special skin cells. The size of the scales can vary: in those they are almost microscopic, while in the Indian longhorned beetle they are several centimeters in diameter. Scales are distinguished by great diversity, both in their strength and in quantity, composition and a number of other characteristics.
The skin of fish contains chromatophores (pigment cells), when they expand, the pigment grains spread over a significant area, making the color of the body brighter. If the chromatophores are reduced, then the pigment grains will accumulate in the center and most of the cell will remain uncolored, due to which the body of the fish will become paler. When pigment grains of all colors are evenly distributed inside the chromatophores, the fish has a bright color, and if they are collected in the centers of the cells, the fish will be so colorless that it may even appear transparent.
If only yellow pigment grains are distributed among the chromatophores, the fish will change its color to light yellow. All the diversity of fish coloration is determined by chromatophores. This is especially true in tropical waters. In addition, the skin of fish contains organs that sense the chemical composition and temperature of the water.
From all of the above, it becomes clear that the skin of fish performs many functions at once, including external protection, protection from mechanical damage, communication with the external environment, communication with relatives, and facilitating gliding.
The role of color in fish
Pelagic fish often have a dark back and a light-colored belly, such as the abadejo fish, a member of the cod family. In many fish that live in the middle and upper layers of water, the color of the upper part of the body is much darker than the lower part. If you look at such fish from below, then its light belly will not stand out against the light background of the sky shining through the water column, which camouflages the fish from the sea predators lying in wait for it. In the same way, when viewed from above, its dark back merges with the dark background of the seabed, which protects not only from predatory sea animals, but also from various fishing birds.
If you analyze the coloration of fish, you will notice how it is used to imitate and camouflage other organisms. Thanks to this, the fish demonstrates danger or inedibility, and also gives signals to other fish. IN mating season, many species of fish tend to acquire very bright colors, while the rest of the time they try to blend in with their environment or imitate a completely different animal. Often this color camouflage is complemented by the shape of the fish.
Internal structure of fish
The musculoskeletal system of fish, like that of land animals, consists of muscles and a skeleton. The skeleton is based on the spine and skull, consisting of individual vertebrae. Each vertebra has a thickened part called the vertebral body, as well as lower and upper arches. Together, the upper arches form a canal in which the spinal cord is located, which is protected from injury by the arches. In the upper direction, long spinous processes extend from the arches. In the trunk part, the lower arches are open. In the caudal part of the spine, the lower arches form a canal through which blood vessels pass. The ribs are adjacent to the lateral processes of the vertebrae and perform a number of functions, primarily protecting the internal organs and creating the necessary support for the muscles of the trunk. The most powerful muscles in fish are in the tail and back.
The skeleton of a fish includes bones and bony rays of both paired and unpaired fins. In unpaired fins, the skeleton consists of many elongated bones attached to the thickness of the muscles. There is a single bone in the abdominal girdle. In the free ventral fin, the skeleton consists of many long bones.
The skeleton of the head also includes a small cranium. The bones of the skull serve as protection for the brain, but most of the skeleton of the head is occupied by the bones of the upper and lower jaws, the bones of the gill apparatus and the eye sockets. Speaking about the gill apparatus, we can primarily note the large gill covers. If you lift the gill covers slightly, then underneath you can see paired gill arches: left and right. Gills are located on these arcs.
As for the muscles, there are few of them in the head; they are located mostly in the area of the gill covers, on the back of the head and jaws.
The muscles that provide movement are attached to the skeletal bones. The main part of the muscles is evenly located in the dorsal part of the animal's body. The most developed are the muscles that move the tail.
The functions of the musculoskeletal system in the body of fish are very different. The skeleton serves as protection for internal organs, bony fin rays protect the fish from rivals and predators, and the entire skeleton in combination with muscles allows this inhabitant of the waters to move and protect itself from collisions and impacts.
Digestive system in fish
The digestive system begins with a large mouth, which is located in front of the head and is armed with jaws. There are large small teeth. Behind the oral cavity is the pharyngeal cavity, in which you can see the gill slits, which are separated by interbranchial septa on which the gills are located. Outside, the gills are covered with gill covers. Next is the esophagus, followed by a fairly voluminous stomach. Behind it is the intestine.
The stomach and intestines, using the action of digestive juices, digest food, and gastric juice acts in the stomach, and in the intestine several juices are secreted by the glands of the intestinal walls, as well as the walls of the pancreas. Bile coming from the liver and gallbladder is also involved in this process. Water and food digested in the intestines are absorbed into the blood, and undigested remains are thrown out through the anus.
A special organ that is found only in bony fish is the swim bladder, which is located under the spine in the body cavity. The swim bladder arises during embryonic development as a dorsal outgrowth of the intestinal tube. In order for the bladder to be filled with air, the newly born fry floats to the surface of the water and swallows air into its esophagus. After some time, the connection between the esophagus and the swim bladder is interrupted.
It is interesting that some fish use their swim bladder as a means by which they amplify the sounds they make. True, some fish do not have a swim bladder. Usually these are those fish that live on the bottom, as well as those that are characterized by vertical rapid movements.
Thanks to the swim bladder, the fish does not sink under its own weight. This organ consists of one or two chambers and is filled with a mixture of gases, which in its composition is close to air. The volume of gases contained in the swim bladder can change when they are absorbed and released through the blood vessels of the swim bladder walls, as well as when air is swallowed. Thus, the specific gravity of the fish and the volume of its body can change in one direction or another. The swim bladder provides the fish with balance between its body mass and the buoyant force acting on it at a certain depth.
Gill apparatus in fish
As a skeletal support for the gill apparatus, fish serve four pairs of gill arches located in a vertical plane, to which the gill plates are attached. They consist of fringe-like gill filaments.
Inside the gill filaments there are blood vessels that branch into capillaries. Gas exchange occurs through the walls of the capillaries: oxygen is absorbed from the water and carbon dioxide is released back. Thanks to the contraction of the muscles of the pharynx, as well as due to the movements of the gill covers, water moves between the gill filaments, which have gill rakers that protect the delicate soft gills from clogging them with food particles.
The circulatory system in fish
Schematically, circulatory system fish can be depicted as a closed circle consisting of vessels. The main organ of this system is the two-chamber heart, consisting of an atrium and a ventricle, which ensures blood circulation throughout the animal’s body. Moving through the vessels, blood ensures gas exchange, as well as the transfer of nutrients in the body, and some other substances.
In fish, the circulatory system includes one circulation. The heart sends blood to the gills, where it is enriched with oxygen. This oxygenated blood is called arterial blood, and is carried throughout the body, distributing oxygen to the cells. At the same time, it is saturated with carbon dioxide (in other words, it becomes venous), after which the blood returns back to the heart. It should be recalled that in all vertebrates, the vessels leaving the heart are called arteries, while those returning to it are called veins.
The excretory organs in fish are responsible for removing metabolic end products from the body, filtering blood and removing water from the body. They are represented by paired kidneys, which are located along the spine by the ureters. Some fish have a bladder.
In the kidneys, excess fluid, harmful metabolic products and salts are extracted from the blood vessels. The ureters carry urine to bladder, from where it hits outward. Externally, the urinary canal opens with an opening located slightly behind the anus.
Through these organs, the fish removes excess salts, water and metabolic products harmful to the body.
Metabolism in fish
Metabolism is the totality of chemical processes occurring in the body. The basis of metabolism in any organism is the construction of organic substances and their breakdown. When complex organic substances enter the fish’s body along with food, during the process of digestion they are transformed into less complex ones, which, being absorbed into the blood, are carried throughout the cells of the body. There they form the proteins, carbohydrates and fats required by the body. Of course, this uses up the energy released during breathing. At the same time, many substances in cells break down into urea, carbon dioxide and water. Therefore, metabolism is a combination of the process of construction and breakdown of substances.
The intensity with which metabolism occurs in a fish’s body depends on its body temperature. Since fish are animals with variable body temperatures, that is, cold-blooded, their body temperature is in close proximity to the ambient temperature. As a rule, the body temperature of fish does not exceed the ambient temperature by more than one degree. True, in some fish, for example tuna, the difference can be about ten degrees.
Nervous system of fish
The nervous system is responsible for the coherence of all organs and systems of the body. It also ensures the body’s response to certain changes in the environment. It consists of the central nervous system (spinal cord and brain) and the peripheral nervous system (branches extending from the brain and spinal cord). The fish brain consists of five sections: the anterior, which includes the optic lobes, the middle, intermediate, cerebellum and medulla oblongata. In all active pelagic fish, the cerebellum and optic lobes are quite large, since they need fine coordination and good vision. The medulla oblongata in fish passes into the spinal cord, ending in the caudal spine.
With the help of the nervous system, the fish’s body responds to irritations. These reactions are called reflexes, which can be divided into conditioned and unconditioned reflexes. The latter are also called innate reflexes. Unconditioned reflexes manifest themselves in the same way in all animals belonging to the same species, while conditioned reflexes are individual and are developed during the life of a particular fish.
Sense organs in fish
The sense organs of fish are very well developed. The eyes are able to clearly recognize objects at close range and distinguish colors. Fish perceive sounds through the inner ear located inside the skull, and smells are recognized through the nostrils. In the oral cavity, the skin of the lips and antennae, there are taste organs that allow fish to distinguish between salty, sour and sweet. The lateral line, thanks to the sensitive cells located in it, reacts sensitively to changes in water pressure and transmits corresponding signals to the brain.
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Pisces use many different methods to communicate. Of course, not as much as humans or other higher vertebrates. To communicate certain information to surrounding fish or other animals, fish can use chemical, electrolocation, sound and, as it turned out, visual methods, that is, they use “sign language” for communication. And although fishermen, unlike aquarists, divers or underwater hunters, are less likely to look a live fish in the eyes, some basic fish language can be learned.
Familiarization
The visible signals that fish can give to fish or other animals around them can be divided into several main groups. The first group is spawning postures or even gestures and facial expressions. After all, the movements of the fins can be called gestures, and the slightly open and even curved mouth can be called facial expressions.
The second group of visual signals demonstrates aggression, attack, and they indicate that this individual is “on the warpath.” There is also large group defensive gestures. This is not open aggression, but such gestures clearly show that we are peaceful fish, but “our armored train is on a siding.” Fish demonstrate these gestures more often than others.
The same group of gestures applies to protecting the territory, and to protecting one’s found (caught) food object, and to protecting the cubs.
Another important visual stimulus is the color of the fish. In a sufficient number of fish species, under stress, during spawning, during an aggressive attack or defense of their “good,” a color change occurs, which signals something out of the ordinary. Something similar happens to a person when, out of anger, shame or tension, he blushes and thereby betrays himself.
Unfortunately, the sign language of fish has not yet been fully studied and is by no means for all species, but still, knowledge of the general principles of gestural communication of fish will help to understand fish. By the way, scientists suggest that fish of each species have a personal sign language, which is understood very well by closely related species and much worse by species that are far apart in their position in the taxonomy.
Gestures of aggression and defense
These gestures may, of course, vary among fish of different species, but they have much in common and are understandable to other fish. Greatest Animal Behavior Researcher, Laureate Nobel Prize Konrad Lorenz said: “Aggression is one of the most important factors maintaining the community structure of most animal groups."
Lorenz pointed out that the existence of groups with close individual connections between individuals is possible only in animals with a sufficiently developed ability for directed aggression, in which the union of two or more individuals contributes to better survival.
In fish, the key aggressive gesture can be considered this: one of the fish turns to the other and begins to open its mouth wide (this is how dogs, wolves and other land animals grin). This gesture can be deciphered as a gesture of a frontal threat (attack).
So if a shark grins at you, leave quickly. While the mouth is just opening, this is some kind of beginning of a threat, territorial defense or any defensive gesture.
An important key point not only of this aggressive gesture, but also of other gestures of the same group: a fish with an open mouth seems larger, and therefore scarier and more impressive. At the same time, her attack looks more convincing and effective.
By the way, spreading the pectoral fins to the sides, protruding gill covers, and inflating the body with various tetraodons also leads to a general increase in the body volume of the frightening fish.
Male fish use certain poses of aggression and active defense to conquer females before spawning. There is no talk of direct use of gestures at this moment, but the female sees how big and serious the suitor is in front of her.
These “exaggeration” poses are very important for fish. After all, they grow throughout their lives, and for them size plays a primary role. Adult individuals, already showing aggressive behavior with all their might, are often large in size.
And the one who is larger is stronger, and older, and more experienced, and more important. That is, he has the right to food, territory, and the best female. Therefore, fish often try to visually exaggerate their size.
An exaggeration of size that frightens the enemy is also achieved by occupying a higher point in space. It is enough to force your opponent to look up, and he will feel inferior to you. Demonstration of the sides of the body and fluttering of the caudal fin and the entire body is often a manifestation of spawning behavior, that is, spawning gestures, or releasers.
However, in some fish (for example, ruffes and other perches), such a display of the sides and trembling of the tail is a typical aggressive gesture. This gesture of some fish is called a “side threat”. Unlike the “frontal threat”, it does not look so intimidating.
The spreading of the fins, often accompanied by trembling (or fluttering, or even shaking of the body), can be interpreted, depending on the situation, as aggression, as active defense, and as gestures of spawning behavior.
And in many territorial fish, such lateral displays, which are accompanied by vibrations of the body and spreading of the fins, have a dual function. For fish of the same species, but of the opposite sex, this is an attractive maneuver, showing what a beautiful, large and wonderful partner is swimming nearby.
And for relatives of the same sex, these gestures mean one thing: this is my female and my place, and you can leave! If one male (or female) spreads his fins, and his opponent, on the contrary, folds them, this means the latter’s complete surrender.
When the enemy in response inflates his fins and vibrates his body, this means that he is accepting the battle and there will be a show. A very important evolutionary point is the demonstration of aggression instead of a direct attack. Indeed, in its original form, aggression involves attacking an object, causing physical damage to it, or even killing it.
In the process of animal evolution, an aggressive attack was replaced by a demonstration of the threat of the possibility of an attack, especially during clashes between individuals of the same species. A demonstration, by causing fear in the enemy, allows you to win a skirmish without resorting to a fight, which is very dangerous for both sides.
Physical confrontation is replaced by psychological confrontation. Therefore, developed aggressive behavior, including many threats and frightening actions, is useful for the species, and for well-armed species it is simply life-saving.
This is why Lorenz argued that well-formed aggressive behavior is one of the remarkable achievements of natural selection and is essentially humane.
In fish, one of the main weapons of demonstration (instead of attack) is spines in the fins, spiny gill covers or plaques on the body. That is, the easiest way to scare an enemy is by showing him the means of defense and attack that this type of animal has.
Therefore, the fish, threatening, spread their fins and raise their spines; many stand upright in the water, exposing them to the enemy.
The fight process in fish consists of five to six successive phases:
- warning with taking the appropriate posture;
- excitement of opponents, usually accompanied by a change in color;
- bringing fish closer together and demonstrating a threat pose;
- mutual blows with the tail and mouth;
- retreat and defeat of one of the opponents.
There are also phases of breaks to relieve tension and to rest during the battle or demonstration of strength.
Coloring and body pattern like spawning releasers
There are a lot of such visual and identification signals. During spawning, when the fish has a special hormonal background, many species change color and pattern - this is a signal that it is ready to reproduce.
For reliability, chemical and other signals also work actively, so that the fish is not mistaken and the species continues to exist. In addition to spawning, coloring and pattern help fish during schooling: often stripes on the body serve as a visual stimulus, helping thousands of fish stay close and correctly positioned relative to each other.
Coloring makes it possible to recognize your relative or, conversely, an enemy and dangerous individual. Many fish, especially those in which visual signals play an important role (pike, perch, pike perch and others), remember well external features“our own” and “foreign” fish. Often two or three “lessons” are enough for the fish to remember well the color and pattern of the hostile fish.
Sometimes not only the color of the entire body, but also the color of individual fins (for example, abdominal or pectoral), or individual brightly colored areas on the body (abdomen, back, head) signal to potential partners that “ready to spawn!”
A spot on the abdomen of many females indicates that there is a lot of caviar in the abdomen, it is enlarged and bright. However, in most cases, bright coloring is destructive outside of spawning: peaceful fish it unmasks itself in front of predators, and, on the contrary, reveals the predator ahead of time.
So most of the fish in our reservoirs during the normal non-spawning period have a gray, inconspicuous appearance, and developed gesticulation is all the more important for them.
In addition to spawning behavior or identification of “friend” or “alien,” coloration can work as a factor determining status.
The brighter the color and clearer the pattern, the higher the social status of this individual. This is not always the case, but it is often the case. Fish can use their coloration to demonstrate threat (strong, intense coloration) or submission (less bright or dull coloration), usually this is supported by appropriate gestures that reinforce the information. Bright coloring is actively used by fish that protect their offspring, raise young and drive away other fish that are dangerous to the young. It also helps juveniles identify their parents and notice them among other fish.
IN parental behavior In fish, not only the language of body coloring is very developed, but also the language of gestures. The young quickly remember that the flapping of the pelvic fins and the pressed pectoral fins mean the call “swim to mom”; a bend of the body and a slightly open mouth - “swim after me”; fins spread out are a command to hide in cover.
For normal relationships between parents and young, it is necessary to suppress certain reactions. Very interesting examples of this have been observed in fish. Some chromis (family Cichlids) carry young fish in their mouths; At this time, adult fish do not feed at all.
A funny case is described with a male of one species of chromis, whose representatives every evening transfer the young to the “bedroom” - a hole dug in the sand. This “father” was collecting fry in his mouth, grabbing the ones that had strayed to the side one by one, and suddenly he saw a worm: after hesitating a little, he finally spat out the fry, grabbed and swallowed the worm, and then again began to collect the “cubs” to transfer them to the hole .
A straightened, standing dorsal fin indicates the beginning aggressive behavior(for example, when protecting one’s territory), and about an invitation to spawn.
Rituals and demonstrations
To understand the sign language of fish, you need to know their rituals and the meaning of different poses and gestures, which say a lot about the fish’s intentions. Rituals and demonstrative acts of behavior exhibited by animals in conflict situations can be divided into two groups: rituals of threat and rituals of pacification, inhibiting aggression from stronger relatives. Lorenz identified several main features of such rituals.
Demonstrative exposure of the most vulnerable part of the body. It is very interesting that dominant animals often demonstrate this behavior. So, when two wolves or dogs meet, the stronger animal turns its head away and exposes to its opponent the area of the carotid artery, curved towards the bite.
The meaning of such a demonstration is that the dominant signals in this way: “I’m not afraid of you!” This is more likely to apply to more highly developed animals, but some fish also exhibit similar behavior. For example, cichlids show folded fins and caudal peduncle to a strong enemy.
Fish have organs that can be called organs of ritual behavior. These are fins and gill covers. Ritual ones are modified fins, which in the process of evolution turn into thorns or spines or, conversely, into veil formations. All these “decorations” are clearly demonstrated in front of other individuals of their species, in front of a female or a rival. Coloring can also be ritualistic.
For example, tropical fish have a false “eye” - a bright spot in the upper corner of the dorsal fin that imitates the eye of a fish. The fish exposes this corner of the fin to the enemy, the enemy grabs onto it, thinking that it is an eye and that he will now kill the victim.
And he just rips out several rays of the dorsal fin with this bright spot, and the victim swims away safely almost unharmed. Obviously, in the course of evolution, both the decorations themselves and the ways of displaying them developed in parallel.
The demonstration of signal structures carries vital information that indicates to other individuals the gender of the demonstrating animal, its age, strength, ownership of a given area of the area, etc.
Ritual demonstrations of territorial behavior among fish are very important and interesting. The forms of aggressive territorial behavior themselves are far from being limited to direct attacks, fights, chases, etc. One can even say that such “harsh” forms of aggression, associated with inflicting wounds and other damage to the enemy, are not such a common phenomenon in the general system of individualization of territory.
Direct aggression is almost always accompanied by special “ritual” forms of behavior, and sometimes the protection of an area is completely limited to them. And the clashes themselves on territorial grounds are relatively rarely accompanied by causing serious damage to the enemy. Thus, frequent fights of goby fish at the boundaries of areas are usually very short-lived and end with the flight of the “intruder”, after which the “owner” begins to swim vigorously in the reclaimed area.
Fish actively mark their territory. Each species does this in its own way, depending on which sensory systems prevail in a given species. Thus, the territory is visually marked by species that live in small, easily visible areas. For example, the same coral fish. A clear, bright, unusual and different from other fish body pattern (and coloring) - all this in itself indicates that the owner of the population of this species is located in this area.
Hierarchy and poses of fish with gestures
The first meeting of animals rarely goes without some tension, without a mutual manifestation of aggressiveness. There is a fight, or individuals demonstrate their hostility with decisive gestures, threatening sounds. However, after the relationship is cleared up, fights rarely occur. Meeting again, the animals unquestioningly give way, food or other object of competition to a stronger rival.
The order of subordination of animals in a group is called hierarchy. Such orderliness of relationships leads to a reduction in energy and mental costs that arise from constant competition and clarification of relationships. Animals at the lower levels of the hierarchy, subject to aggression from other members of the group, feel oppressed, which also causes important physiological changes in their body, in particular the occurrence of an increased stress response. It is these individuals who most often become victims natural selection.
Each individual is either superior in strength to its partner or inferior to it. Such a hierarchical system is formed when fish collide in the struggle for a place in a reservoir, for food and for a female.
The fish just opened its mouth and raised its fin, and its size visually increased by almost 25%. This is one of the most accessible and common ways to raise your authority in the animal world.
In the early stages of establishing a hierarchy, a lot of fights occur between fish (which are inherently hierarchical in principle). After the final establishment of the hierarchy, aggressive clashes between fish individuals practically cease, and the order of subordination of individuals is maintained in the population.
Usually, when a high-ranking fish approaches, subordinate individuals yield to it without resistance. In fish, size is most often the main criterion for dominance in the hierarchical ladder.
The number of collisions in a group of animals increases sharply when there is a lack of food, space or other living conditions. Lack of food, causing more frequent collisions of fish in a school, causes them to spread out somewhat to the sides and take over additional feeding area.
Fatal fights between very aggressive fish species in fish farms and aquariums are observed much more often than in natural conditions. This can easily be explained by stress and the inability to separate opponents. A kind of eternal ring. Therefore, aquarists know how important it is to provide plenty of hiding places in a pond if the fish are territorial. It’s even safer to keep them separate.
Each individual is either superior in strength to its partner or inferior to it. Such a hierarchical system is formed when fish clash in the struggle for a place in a reservoir, for food and for a female.
The lowest links in the fish in the hierarchical ladder should demonstrate postures of submission, humility and appeasement. What does a losing fish do? First of all, she raises the “white flag”, that is, she folds her fins, removes spikes, spines and teeth (sharks). These attributes of aggressiveness are removed until better times, that is, before meeting with an even weaker opponent.
The size of individuals decreases before our eyes. As far as possible, of course. That is, the losing fish-outsider demonstrates to the enemy: “I am small and unarmed, I am not afraid of you!”. And a strong victorious opponent also understands that he no longer needs to demonstrate his strength, and closes his mouth, assumes a horizontal position, folds his fins, removes thorns and spines (if any, of course).
Sometimes a defeated fish turns belly up and this also demonstrates its defenselessness. I deliberately do not provide data on specific species here, since there are very few of them, and many have not yet been statistically confirmed.
I hope that interesting information will help anglers to better understand the fish, once again not to frighten and harm both a particular fish and a flock or population as a whole.
Source: Ekaterina Nikolaeva, Fish with us 3/2013 159
Gustera
Silver bream fish. The silver bream differs from the above-described species of bream solely in the number and location of the pharyngeal teeth, of which there are not five, but seven on each side, and moreover, in two rows. In body shape it is very similar to a young bream, or rather, a bream, but has a smaller number of rays in the dorsal (3 simple and 8 branched) and anal (3 simple and 20-24 branched) fins; in addition, its scales are noticeably larger, and its paired fins are reddish in color.
The body of the silver bream is strongly flattened, and its height is at least a third of its entire length; her nose is blunt, her eyes are large and silvery; the back is bluish-gray, the sides of the body are bluish-silver; unpaired fins gray, and paired ones are red or reddish at the base, dark gray towards the apex. However, this fish, depending on age, time of year and local conditions, presents significant modifications.
Guster never reaches a significant size. For the most part it is no more than one pound and less than a foot in length; One and a half and two pound ones are less common, and only in a few places, for example in the Gulf of Finland. Lake Ladoga, it weighs up to three pounds. This fish has a much wider distribution than syrty, bluefish and glazach.
Gustera is found in almost all European countries: France, England, Sweden, Norway, throughout Germany, Switzerland, and it seems to be absent only in Southern Europe. In all the above-mentioned areas, it belongs to very common fish. In Russia, the silver bream is found in all rivers, sometimes even small rivers, also in lakes, especially in the northwestern provinces, and flowing ponds; in Finland it reaches 62° N. sh.; also found in the northern parts Lake Onega, and in northern Russia it goes even further - to Arkhangelsk.
It seems that it no longer exists in Pechora, and in Siberia it was found only recently (Varpakhovsky) in the river. Iset, a tributary of the Tobol. There is no silver bream in the Turkestan region, but in Transcaucasia it has so far been found at the mouth of the Kura River and in Lake. Paleostome, off the coast of the Black Sea. Silver bream is a sluggish, lazy fish and, like bream, loves quiet, deep, fairly warm water, with a silty or clayey bottom, which is why it is very often found with this latter.
It lives in one place for a long time and most willingly stays near the very shores (hence its French name - la Bordeliere and Russian berezhnik), especially in the wind, since the shafts, eroding the banks, and in shallow places the very bottom, reveal various worms and larvae. In no large quantities it apparently lives at the mouths of rivers and at the seaside itself, as, for example, at the mouths of the Volga and in the Gulf of Finland between St. Petersburg and Kronstadt.
In spring and autumn, the silver bream is found in extremely dense flocks, which, of course, is where its common name comes from. However, it rarely makes very long journeys and almost never reaches, for example, the middle reaches of the Volga, where its own local bream lives. In general, the main mass of these fish accumulate in the lower reaches of rivers, in the sea, and, like very many others, they make regular periodic movements: in the spring they go up for spawning, in the fall for wintering.
Entering wintering grounds in the fall, they lie down in holes under the rifts like this large masses that in the lower reaches of the Volga it happens that up to 30 thousand pieces are pulled out in one ton. The food of the silver bream is almost the same as that of other types of bream: it feeds exclusively on mud and small mollusks, crustaceans and worms contained in it, most often bloodworms, but it also destroys the eggs of other fish, especially (according to Bloch’s observations) rudd caviar.
Spawning of the silver bream begins very late, b. hours after the end of bream spawning - at the end of May or at the beginning of June, in the south a little earlier. At this time, its scales change color, and the paired fins acquire a brighter red color; in males, in addition, small granular tubercles develop on the gill covers and along the edges of the scales, which then disappear again. Usually, small silver bream spawns earlier, large ones later.
In the Gulf of Finland, other fishermen distinguish two breeds of silver bream: one breed, according to them, is smaller, lighter in color, spawns earlier and is called Trinity (based on the time of spawning), and the other breed is much larger (up to 3 pounds), darker in color, spawns later and is called Ivanovskaya. According to Bloch’s observations, in Germany the largest silver bream spawns first, followed by the smallest one a week or nine days later.
The silver bream chooses grassy and shallow bays as a spawning site and spawns eggs extremely noisily, like bream, but incomparably quieter than it: at this time it sometimes even happens to catch them with your hands; then they catch her in the muzzle, winged and nonsense by the pounds. It usually spawns from sunset to ten o'clock in the morning, and each age finishes the game at 3-4 at night, but if cold weather interferes, then in one day.
In a medium-sized female, Bloch counted more than 100 thousand eggs. According to Sieboldt, the silver bream becomes capable of reproduction very early, not yet reaching 5 inches in length, so we must assume that it spawns in its second year. The main catch of silver bream is carried out in the spring - with seines, but in the lower reaches of rivers, especially on the Volga, even greater catches of this fish occur in the fall. The most full information about the crucian fish - here.
Silver bream generally belongs to low-value fish and is rarely prepared for future use, unless it is caught in very large quantities. Salted and dried silver bream on the lower Volga is sold under the name tarani; in the rest of the Volga region she b. h. is sold fresh and has only local sales. However, it is very suitable for fish soup and is held in rather greater esteem in the Volga provinces, where there is a saying about it: “Large silver bream is tastier than small bream.”
Where there is a lot of silver bream, it takes the bait very well, especially after spawning. In some places they usually fish for silver bream with a worm, from the bottom, like bream, and its bite is similar to the latter’s bite; The silver bream, even more often than the bream, drags the float to the side without submerging it, and often hooks itself. This is perhaps the most daring and annoying fish, which is pure punishment for anglers fishing with bait.
It has been noticed that she takes best at night. According to Pospelov, the silver bream on the river. Teze (in Vladimir province) is caught as if with pieces of salted herring. In Germany in the fall it also goes well for bread with honey, and on the Volga it is very often caught in winter from ice holes (using a worm). The winter bite of the silver bream has the usual character - it first twitches, then slightly drowns. For catching catfish, pike and large perch, silver bream is one of the the best attachments, since it is much more tenacious than other types of bream.
In many places in Russia, for example. in the Dnieper, Dniester, on the middle and lower Volga, occasionally - usually alone and in schools of other fish, b. including silver bream and roach (roach) - there is one fish that occupies, as it were, the middle between bream, silver bream and roach (Abramidopsis), on the river. In Mologa this fish is called ryapusa, in Nizhny Novgorod, Kazan and on the Dnieper - all fish, all fish, on the grounds that they resemble different carp fish: blue bream, silver bream, roach, rudd.
According to fishermen, as well as some scientists, this is a bastard from bream and roach or silver bream and roach. In Kazan, one fisherman even claimed to prof. Kessler that all fish hatch from roach eggs fertilized by male silver bream. In terms of body shape and pharyngeal teeth, this cross is still closer to the genus Abramis.
The height of its body is about 2/7 of the entire length, the mouth occupies the top of the snout and lower jaw somewhat curled upward; the scales are larger than those of other breams, and the anal fin contains only 15-18 unbranched rays; the lower lobe of the caudal fin is barely longer than the upper one, before Abramidopsis is already approaching the roach. It would be more correct to assume that this is mostly a cross between bream and roach.
A similar cross is Bliccopsis abramo-rutilus Holandre, which probably originated from silver bream and roach and was occasionally found here and there alone, as in Central Europe, and in Russia. According to Kessler, Bliccopsis is also found in lake. Paleostom (at the mouth of Rion in the Caucasus). The body of the silver bream is tall, strongly compressed laterally, covered with thick, tightly fitting scales. Her head is relatively small. The mouth is small, oblique, semi-inferior, retractable.
The eyes are big. The dorsal fin is high, the anal fin is long. The back is bluish-gray, the sides and belly are silver. The dorsal, caudal and anal fins are gray, the pectoral and ventral fins are yellowish, sometimes reddish, which is how it differs in appearance from bream. In addition, the silver bream, unlike the bream, has larger scales, especially at the dorsal fin, as well as on the back; behind the back of the head it has a groove not covered with scales.
The silver bream lives in rivers, lakes and ponds. In rivers, it sticks to places with a slow flow and considerable depth, as well as in bays, backwaters, oxbow lakes, where the bottom is sandy and clay with a small admixture of silt. It is most numerous in lakes and in lowland areas of rivers. Large individuals live in bottom layers of water, deep pools, holes and in open areas of lakes and reservoirs.
The smaller silver bream prefers to stay in coastal areas among sparse thickets. At the same time, small individuals usually stay in large flocks. Gustera is characterized by a sedentary lifestyle. In summer its flocks are small. With the onset of autumn cold weather, they increase in size and move to the pits. With the onset of spring floods, its flocks go to feeding areas.
As spawning time approaches, after the water warms up, flocks of silver bream increase and move to the spawning grounds. At the same time, the lake spawning silver bream goes to the shores in large numbers, and the river bream, leaving the channel, enters small bays and creeks. The silver bream spawns from the end of April to May at a water temperature of 12-20°. With prolonged cold snaps, spawning can be delayed until June.
The white bream spawns in portions, but there are females that spawn at once. Its spawning occurs amicably, mainly in the evening and morning with a short night break. Before spawning, they become bright silver, the pectoral and pelvic fins acquire an orange tint. Lumps of pearly rash appear on the head and upper body of spawning males. Soon after spawning, all mating changes disappear.
In the Dnieper, on the site of the now existing Kiev reservoir, three-year-old females of the silver bream had an average of 9.5 thousand eggs, six-year-olds - 22 thousand, and three years after the formation of the reservoir, more than 16 thousand eggs were found in three-year-old females, in six-year-olds - more than 80 thousand pieces, i.e., in the conditions of the reservoir, its fertility increased by 2-3 times.
The silver bream becomes sexually mature at two or three years of age, and in the spawning herd, males mature predominantly earlier than females. In older age groups of the spawning stock, there are significantly fewer males than females. The silver bream grows slowly. For example, in the lower reaches Southern Bug yearlings had an average body length of 3.3 cm, three-year-olds - 10.2 cm, six-year-olds - 16.9 cm.
Until puberty, both sexes grow equally, but after puberty, the growth of males slows down somewhat. Juvenile silver bream in Dnieper reservoirs feed on crustaceans and chironomid larvae. To a lesser extent, it consumes algae, caddisflies, spiders and water bugs. Adult fish feed on higher aquatic plants, worms, mollusks, crustaceans, larvae and pupae of mosquitoes and other insects.
The main feeding grounds for small silver bream (10-15 cm long) are located mainly in the coastal zone. Large fish, feeding mainly on mollusks, feed in places more distant from the shore. Fish with a length of 25-32 cm, which have significant fatty deposits in their intestines, feed weaker. As the body size of the silver bream increases, the number of crustaceans and insect larvae in its food decreases and the number of mollusks increases.
She switches to feeding on mollusks with a body length of 13-15 cm or more. Depending on the composition and development of the food supply, the ratio of food organisms in the food composition of fish of the same size is not the same. For example, fish 10-12 cm long in the coastal zone feed mainly on insect larvae, and in deeper places on crustaceans, which corresponds to the distribution of these organisms in reservoirs.
Gustera is widespread in Europe. It is absent in the rivers of the Arctic Ocean and in Central Asia. In the CIS, it lives in the basins of the Baltic, Black, Azov and Caspian Seas. In Ukraine, it lives in the basins of all rivers, excluding the rivers of Crimea and mountainous sections of other rivers.
List of fish: whitefish species, muksun, omul and vendace
There are many salmon fish, one of the families is whitefish, a numerous, little-studied fish genus with variable characteristics. Representatives of this family have a laterally compressed body and a small mouth for their size, which causes a lot of inconvenience for amateurs. fishing on the fishing rod. The lip of a whitefish often cannot withstand the load when it is pulled out of the water, and when the lip breaks off, the fish leaves.
Due to the similarity of the silhouette of the whitefish's head with the head of a herring, whitefish are also called herring, and only the adipose fin clearly indicates their salmon origin. Extremely high degree the variability of characters still does not allow us to establish the exact number of their species: in each lake it is possible to establish its own special species, for example, only in lakes Kola Peninsula 43 forms were identified. Currently, work is underway to combine similar forms into one species, which should lead to the systematization of fish species of the whitefish family.
General description of the family
On the territory of Russia there are over a hundred varieties of fish of this family, which have excellent taste and other beneficial properties. Its habitat is almost all bodies of water from the Kola Peninsula in the west to the Kamchatka and Chukotka Peninsulas in the east. Although this fish belongs to the salmon family, its meat is white, sometimes pinkish in color. Often, even experienced fishermen do not even suspect that the Baikal omul is the same whitefish. Here is a small list of the names of fish of the whitefish family:
- largemouth and European vendace (ripus), Atlantic and Baltic whitefish;
- whitefish Volkhovsky, Bauntovsky and Siberian (Pyzhyan), Baikal omul;
- Muksun, Tugun, Valaamka and Chir (Shokur).
This diverse fish does not have a single appearance, but all members of the family have uniform silvery scales and darkened fins. The adipose fin, a distinctive feature of all salmon fish, is also common feature fish of the genus whitefish. A distinctive feature of females is their scales; unlike the scales of males, they are larger and have a yellowish tint.
Like salmon, whitefish can be found in both fresh and salt water. Depending on this, two groups of whitefish are distinguished:
- freshwater – lake and river;
- anadromous or sea whitefish.
Gallery: whitefish species (25 photos)
habits and preferences
A quality common to the entire family is life in a flock, which is formed according to the age of the individuals. Whitefish preferences are uncomplicated cold water, enriched with oxygen, which usually occurs in rapids of rivers and in the depths of lakes. At the same time, a school of whitefish can drive representatives of other fish species out of the pit. As a rule, than bigger fish, the further it goes from the coast.
The ability to spawn in fish of the family appears at the age of about three years, and in some breeds - a year or two later. Spawning of sea and freshwater whitefish takes place in the same conditions - all of them, including lake ones, rise to the upper reaches of rivers and their tributaries. Whitefish lay eggs in the fall, when the water cools to below five degrees. The spawning areas are deep holes and quiet rivers and reaches. Here the eggs are aged until spring, when the fry emerge from the eggs as the water warms.
The diet of the whitefish family, like all predators, is of animal origin: vertebrate and invertebrate insects (worms, larvae and caterpillars, caddis flies and bark beetles), small crustaceans and mollusks, caviar. Depending on the age and, accordingly, the size of the predator itself, it also attacks fish that are smaller than it. But among whitefish there are also lovers of vegetarian food collected from the bottom, as well as omnivores - semi-predators.
Their lifespan is about two decades, but fish of half their age are often caught. The largest whitefish is usually a little more than half a meter long, and small adult breeds are from one to one and a half decimeters.
As a rule, whitefish are divided into separate groups based on mouth position. The mouth can be directed upward - the upper mouth, forward - the terminal, and downward - the lower mouth.
Topmouth are small fish that feed on what they find near the surface of the water. These are insects and invertebrates - worms and caterpillars. Fish with an upper mouth are represented mainly by the European vendace (ripus) and the larger Siberian vendace. The latter is up to half a meter in length, lives in places where rivers flow into the salty waters of the sea, and almost never occurs in lakes. The rhipus is half the size and is an inhabitant of lakes. Both species of vendace are commercially available.
Whitefish with a mouth in front (final) are also considered commercial fish. Omul is a large, over half a meter long fish that, like vendace, lives in the bays of the seas and the mouths of the rivers flowing into the sea, where it rises to spawn. The diet of omul includes crustaceans and small fish. Baikal omul is a lake variety of whitefish. Another lake-river variety is peled fish (curd), in sea water it does not enter, but is as large as vendace and omul, its length is about half a meter. It was also brought into reservoirs Southern Urals, here its size is not so impressive. There is also a small relative of whitefish with a terminal mouth - tugun, which lives in the rivers of Siberia. Its length does not exceed twenty centimeters.
Whitefish with bottom position mouths also live in Russian water bodies; there are seven species of them. But work is currently underway to separate them, and there is no point in providing any information on them.
Freshwater whitefish
The river whitefish breed - by name, is an inhabitant of rivers where it comes from the sea or big lake when moving to spawn. His usual weight is about a kilogram, rarely exceeds two kilograms. River whitefish only winter in lakes; at all other times of the year they lead a river life. In essence, this is a marine or anadromous whitefish acclimatized to river life. The caviar of this species of whitefish is numerous - up to 50 thousand eggs and slightly lighter than trout caviar.
Pechora whitefish, the most famous are omul, it was already mentioned above, peled, whitefish. The peled reaches a length of more than half a meter and a weight of about three kilograms. Chir is much larger, it can weigh up to ten kg, and lives in the lakes of the Pechora River basin and its channels.
The Baikal omul reaches a weight of up to seven kilograms; its food is small epishura crustaceans, and if there are insufficient quantities of them, it switches to eating small fish. Starting in September, the omul rises into the rivers, preparing for spawning. Based on the location of the spawning grounds, subspecies of the Baikal omul are distinguished:
- Angara - early ripening, maturity at five years, but with slow growth;
- Selenga - maturity at seven years, grows quickly;
- Chivyrkuisky - also grows quickly, spawning in October.
The omul finishes spawning when slush already appears on the river and floats back to Lake Baikal for the winter. At one time, the fish was intensively caught by commercial fishermen, and its numbers decreased significantly, but now measures are being taken to artificially reproduce the omul.
Fins organs of movement of aquatic animals. Among invertebrates, P. have pelagic forms of gastropods and cephalopods and setaceous-maxillary. U gastropods P. are a modified leg; in cephalopods, they are lateral folds of skin. The chaetomagnaths are characterized by lateral and caudal wings formed by folds of skin. Among modern vertebrates, cyclostomes, fish, some amphibians, and mammals have P. In cyclostomes there are only unpaired P.: anterior and posterior dorsal (in lampreys) and caudal. In fish, paired and unpaired P. are distinguished. Paired are represented by anterior (thoracic) and posterior (abdominal). In some fish, such as codfish and blennies, the ventral fins are sometimes located in front of the thoracic fins. The skeleton of paired P. consists of cartilaginous or bone rays, which are attached to the skeleton of the limb belts (See limb belts) ( rice. 1
). The main function of paired P. is the direction of movement of fish in a vertical plane (rudders of depth). In a number of fish, the paired P. function as organs of active swimming (see Swimming) or serve for gliding in the air (in flying fish), crawling along the bottom, or movement on land (in fish that periodically emerge from the water, for example, in representatives of the tropical genus Periophtalmus , which, with the help of chest P., can even climb trees). The skeleton of unpaired P. - dorsal (often divided into 2, and sometimes into 3 parts), anal (sometimes divided into 2 parts) and caudal - consists of cartilaginous or bone rays lying between the lateral muscles of the body ( rice. 2
). The skeletal rays of the caudal P. are connected with the posterior end of the spine (in some fish they are replaced by spinous processes of the vertebrae). The peripheral parts of the P. are supported by thin rays of horn-like or bone tissue. In spiny-finned fish, the anterior of these rays thicken and form hard spines, sometimes associated with poisonous glands. Muscles that stretch the lobe of the pancreas are attached to the base of these rays. The dorsal and anal parasites serve to regulate the direction of movement of the fish, but sometimes they can also be organs of forward movement or perform additional functions (for example, attracting prey). The caudal part, which varies greatly in shape in different fish, is the main organ of movement. In the process of the evolution of vertebrates, the P. of fish probably arose from a continuous fold of skin that ran along the back of the animal, went around the rear end of its body and continued on the ventral side to the anus, then divided into two lateral folds that continued to the gill slits; This is the position of the fin folds in the modern primitive chordate - Lancelet a. It can be assumed that during the evolution of animals, skeletal elements formed in some places of such folds and in the intervals the folds disappeared, which led to the emergence of unpaired folds in cyclostomes and fish, and paired ones in fish. This is supported by the presence of lateral folds or venom of spines in the most ancient vertebrates (some jawless, acanthodia) and the fact that in modern fish paired P. have a greater extent of early stages development than in adulthood. Among amphibians, unpaired amphibians, in the form of a fold of skin devoid of a skeleton, are present as permanent or temporary formations in most larvae living in water, as well as in adult caudate amphibians and the larvae of tailless amphibians. Among mammals, P. are found in cetaceans and lilacs that have switched to an aquatic lifestyle for the second time. Gypsy cetaceans (vertical dorsal and horizontal caudal) and lilacs (horizontal caudal) do not have a skeleton; these are secondary formations that are not homologous (see Homology) to the unpaired P. of fish. The paired limbs of cetaceans and lilacs, represented only by the anterior limbs (the hind limbs are reduced), have an internal skeleton and are homologous to the forelimbs of all other vertebrates. Lit. Guide to Zoology, vol. 2, M.-L., 1940; Shmalgauzen II, Fundamentals of Comparative Anatomy of Vertebrate Animals, 4th ed., M., 1947; Suvorov E.K., Fundamentals of Ichthyology, 2nd ed., M., 1947; Dogel V.A., Zoology of invertebrates, 5th ed., M., 1959; Aleev Yu. G., Functional principles of the external structure of fish, M., 1963. V. N. Nikitin.
Great Soviet Encyclopedia. - M.: Soviet Encyclopedia. 1969-1978 .
See what “Fins” are in other dictionaries:
- (pterigiae, pinnae), organs of movement or regulation of body position of aquatic animals. Among invertebrates, pelagics have P. forms of certain mollusks (a modified leg or a fold of skin), chaetognaths. In skullless fish and larvae of fish, the unpaired P.... ... Biological encyclopedic dictionary
Organs of movement or regulation of the position of the body of aquatic animals (some mollusks, chaetognaths, lancelet, cyclostomes, fish, some amphibians and mammals, cetaceans and sirenians). They can be paired or unpaired. * * * FINS… … encyclopedic Dictionary
Organs of movement or regulation of the position of the body of aquatic animals (some molluscs, chaetognaths, lancelet, cyclostomes, fish, some amphibians and mammals, cetaceans and sirenians). There are paired and unpaired fins... Big Encyclopedic Dictionary
