In American taxonomy, the following taxa are distinguished. Taxonomic (systematic) units

Systematics

There are many different types of plants on Earth. It is difficult to navigate in their diversity. Therefore, plants, like other organisms, systematize - distribute, classify into certain groups. Plants can be classified according to their uses. For example, medicinal, spice-flavoring, oil-bearing plants, etc. are isolated.

The most common system that botanists use today is the hierarchical system. It is built on a box-in-a-box basis. Any level of the system hierarchy is called taxonomic rank (taxonomic category).

Taxon- these are actually existing or existing groups of organisms, classified in the process of classification to certain taxonomic categories.

classifying living organisms, scientists attributed them to one or another group, taking into account the similarity (community). Such groups are called taxonomic units, or taxonomic units.

The main taxonomic rank is view (species). Usually under species understand the totality of populations of individuals capable of interbreeding with the formation of fertile offspring, inhabiting a certain area, having a number of common morphophysiological features and types of relationships with abiotic and biotic environments, and separated from other similar populations of individuals by the absence of hybrid forms.

In other words view- This is a group of organisms that are similar in structure, living in a certain area, adapted to similar living conditions and capable of producing fertile offspring.

Genus. A group of species that are similar in many ways is combined into a genus.

Families. Close genera are grouped into families.

Classes. Families with similar characteristics are grouped into classes.

Departments. Classes of plants, fungi and bacteria are combined into departments.

Kingdom. All divisions of plants form the plant kingdom.

Above the view are the genus (genus), family (family), order (ordo), subclass (subclasses), Class (classis), Department (divisio) and kingdom (regnum).

Within the species, smaller systematic units can be distinguished: subspecies (subspecies), variety (varietas), the form (forma); for cultural use category - variety.

Table 1

Main taxonomic ranks of taxonomy of higher plants and examples of taxa

Swedish professor Carl Linnaeus in the 18th century proposed binary nomenclature instead of the cumbersome polynomial. Binary nomenclature was introduced by Kal Liney in 1753. The rules for assigning botanical names to plants are contained in the "International Code of Botanical Nomenclature", which is reviewed at the International Botanical Congresses every 6 years.

The scientific name of the species according to binary nomenclature (double) consists of two Latin words. The first word is the name of the genus, the second is the specific epithet. After the Latin name of the species, the surname or initials of the author who gave the name to the species is abbreviated.

For example, view Triticum aestivum L.. (wheat) consists of two words: genus Triticum– wheat, specific epithet aestivum- soft.

The scientist who first described the taxon is its author. The author's surname is placed after the Latin name of the taxon, usually in an abbreviated form. For example, a letter L. indicates the authorship of Linnaeus (Linneus), DS. – Decandolle, Bge. – Bunge, Com. – V.L. Komarov, etc. AT scientific papers the authorship of taxa is considered mandatory, they are often omitted in textbooks and popular publications.

The Latin name of the family is formed by adding the ending - ceae(cee) or - aceae(acee) to the basis of the name of one of the most common genera of this family. For example, genus Roa(bluegrass) gave the name to the family Roaseae(bluegrass).

Sometimes alternative, traditional, names are allowed, for example, families:

Asteraceae (Asteraceae) – Asteraceae Compositae

legumes ( Fabaceae) - Moth (Leguminosae)

Celery (Apiaceae) – Umbelliferae (Umbelliferae)

Lamiaceae ( Lamiaceae)– Lamiaceae (Labiaceae)

Bluegrass ( Poaceae)– Cereals (Graminea).

Department names usually end with - phyta ( fit), for example, Angiospermophyta- angiosperms, etc. The name of the plant orders ends with - ales

The plant kingdom is divided into two sub-kingdoms:

Lower plants (Thallobionta);

Higher plants (Kormobionta).

Sub-kingdom "lower plants"

The lower plants include the most simply arranged representatives of the plant world. The vegetative body of lower plants does not have a division into organs (stem, leaf) and is represented by a thallus - called thallus .

Lower plants are characterized by the absence of complex internal differentiation, they do not have an anatomical and physiological system of tissues, as in higher plants, the organs of sexual reproduction are lower, unicellular (with the exception of characeae and some brown algae. Lower plants include bacteria, algae, slime molds (myxomycetes), fungi, lichens.

Algae belong to the group of autotrophic organisms. Bacteria (with rare exceptions), myxomycetes and fungi are heterotrophic organisms that need ready-made organic matter. Both seem to complement each other.

Algae are the main producers of organic matter in water bodies. Decomposition organic matter and their mineralization are carried out as a result of the activity of heterotrophic organisms: bacteria and fungi. Due to the processes of decomposition of organic substances, the atmosphere is replenished with carbon dioxide.

Some soil bacteria and blue-green algae are capable of fixing free atmospheric nitrogen. Thus, the biological cycle of substances performed by autotrophic and heterotrophic organisms is inconceivable without the activity of lower plants. In terms of their wide distribution in nature and in numbers, the lower plants outnumber the higher ones.

Sub-kingdom "higher plants"

Higher plants include organisms that have well-defined tissues, organs (vegetative: root and shoot, generative) and individual development (ontogenesis) of which is divided into embryonic (embryonic) and post-embryonic (post-embryonic) periods.

Higher plants are divided into two groups:

Spore (Archegoniophyta);

Seed (Spermatophyta).

spore plants spread through spores. Reproduction requires water. spore plants also called archegonial. The body of higher plants is differentiated into tissues and organs that appeared in them as one of the adaptations for life on land. The most important organs root and the escape divided into stem and leaves. In addition, special tissues are formed in land plants: coverslip, conductive and main.

Integumentary tissue performs protective function protecting plants from adverse conditions. Through conductive tissue metabolism takes place between the underground and aboveground parts of the plant. Main fabric performs various functions: photosynthesizing, supporting, storing, etc.

All spore plants in their life cycle development, the alternation of generations is clearly expressed: sexual and asexual.

The sexual generation is a sprout, or gametophyte- formed from spores, has a haploid set of chromosomes. It performs the function of the formation of gametes (sex cells) in special organs of sexual reproduction; archegonia(from the Greek "arche" - the beginning and "rut" - birth) - female genital organs and antheridia(from the Greek. "Anteros" - blooming) - male genital organs.

The sporangial tissue also has a double set of chromosomes, it divides by meiosis (a method of division), as a result of which spores develop - haploid cells with a single set of chromosomes. The name of the generation "sporophyte" means a plant that forms spores.

Spore plants are divided into the following sections:

Bryophytes (Bryophyta);

Lycophyta (Lycophyta);

Horsetail (Sphenophyta);

Ferns (Pterophyta).

seed plants spread by seeds. Reproduction does not require water.

The main differences between seed plants from higher spores are as follows:

1. Seed plants produce seeds for distribution. They are divided into two departments.

- angiosperms- plants that form seeds enclosed in fruits.

2. In seed plants, there is a further improvement in the life cycle and an even greater dominance of the sporophyte and a further reduction of the gametophyte. The existence of the gametophyte in them is completely dependent on the sporophyte.

3. The sexual process is not associated with a drop-liquid medium, and gametophytes develop and go through a full cycle of their development on a sporophyte. Due to the independence of the process of fertilization from water, immobile male germ cells arose - sperm, which reach the female germ cells - eggs - with the help of a special formation - a pollen tube.

In seed plants, the only mature megaspore remains permanently enclosed within the megasporangium, and here, inside the megasporangium, the development of the female gametophyte and the process of fertilization take place.

Megasporangium in seed plants is surrounded by a special protective cover called the integument. The megasporangium with its surrounding integument is called the ovule. This is really the germ of the seed (ovule), from which, after fertilization, the seed develops.

Inside the ovule, the process of fertilization and development of the embryo takes place. This ensures the independence of fertilization from water, its autonomy.

In the process of development of the embryo, the ovule turns into a seed - the main unit of seed plant dispersal. In the vast majority of seed plants, this transformation of the ovule into a mature seed ready for germination takes place on the mother plant itself.

Primitive seeds, such as cycads, are characterized by the absence of a dormant period. For most seed plants, a more or less long dormant period is characteristic. The rest period has a long biological significance, because it makes it possible to survive the unfavorable season, and also contributes to a more distant settlement.

Internal fertilization, the development of the embryo inside the ovule, and the appearance of a new, extremely effective unit of settlement - the seed - are the main biological advantages of seed plants, which made it possible for them to more fully adapt to terrestrial conditions and achieve a higher development, higher spore plants.

Seeds, unlike spores, have not only a fully formed embryo of the future sporophyte, but also reserve nutrients necessary at the first stages of its development. Dense shells protect the seed from adverse natural factors that are detrimental to most spores.

Thus, seed plants acquired serious advantages in the struggle for existence, which determined their flourishing during the drying up of the climate. It is currently the dominant group of plants.

Seeds are divided into the following departments:

Angiosperms, or flowering (Magnoliophyta);

Let's consider them in more detail

lower plants

In terms of their wide distribution in nature and in numbers, the lower plants outnumber the higher ones. As lower plants are studied, the scope of their use expands and their importance in human life increases.

The modern system of plants is based on the following classification scheme for lower plants:

1. Department of Bacteria.

2. Division Blue-green algae.

3. Department Euglena algae.

4. Department of Green Algae.

5. Department of Chara algae.

6. Department Pyrophytes.

7. Department Golden algae.

8. Department Yellow-green algae.

9. Department of Diatoms.

10. Department Brown algae.

11. Department Red algae.

12. Department of Slime Mold.

13. Department of Mushrooms.

14. Department of Lichens.

Algae – Algae

This sub-kingdom includes algae – the simplest in structure and the most ancient plants. This is an ecological heterogeneous group of phototrophic multicellular, colonial and unicellular organisms that often live in the aquatic environment.

However, the world of algae is very diverse and numerous. Most of them live in or on water. But there are algae that grow in the soil, on trees, on rocks and even in ice. Algae body – it is a thallus or thallus that has neither root nor shoots. Algae do not have organs and various tissues; they absorb substances (water and mineral salts) through the entire surface of the body.

All types of algae are united by the following features:

The presence of photoautotrophic nutrition and chlorophyll;

Lack of strict differentiation of the body into organs;

Well-defined conducting system;

Dwelling in a humid environment;

The absence of an integument.

Algae are distinguished by the number of cells:

- unicellular;

- multicellular (mainly filamentous);

- colonial;

- non-cellular.

There is also a difference in the structure of cells and the pigment composition of algae. In this regard, there are:

- green(with a green tone and slight splashes of yellow);

- blue-green(with pigments of green, blue, red and yellow shades);

- brown(with green and brown pigments);

- red(with pigments various shades red);

- yellow-green(with coloring of corresponding tones, as well as two flagella of different structure and length);

- golden(with pigments that form a golden color, and cells that do not have a shell or are enclosed in a dense shell);

- diatoms(with a strong shell, consisting of two halves, and a brownish color);

- pyrrhophytes(brownish-yellow shade with bare or shell-covered cells);

- euglenoidsseaweed(unicellular, naked, with one or two flagella).

Algae reproduce in several ways:

- vegetative(by simple cell division of the organism's body);

- sexual(fusion of germ cells of a plant with the formation of a zygote);

- asexual(zoospores).

Depending on the type of algae and how favorable the environmental conditions are, the number of generations in just a few years can exceed 1000.

All types of algae, due to the presence of chlorophyll in the cells, form oxygen. Its share of the total volume produced by the plants of the planet Earth is 30-50%. By producing oxygen, algae absorb carbon dioxide, the percentage of which is currently quite high in the atmosphere.

Algae also act as a food source for many other living beings. They feed on mollusks, crustaceans, various types of fish. Their high adaptability to harsh conditions provides high-quality nutrient medium plants and animals high in the mountains, in polar regions, etc.

If there is too much algae in the reservoirs, the water begins to bloom. A number of them, for example, blue-green algae, actively secrete during this period toxic substance. Its concentration is especially high at the surface of the water. Gradually, this leads to the death of aquatic inhabitants and a significant deterioration in water quality, up to waterlogging.

Algae benefit not only the flora and fauna. Mankind also actively uses them. The vital activity of organisms in the past has become for the modern generation a source of minerals, in the list of which it is worth noting oil shale and limestone.

In any classification, there are larger and smaller groups of plants that are related. Large groups are subdivided into smaller ones; and small ones, on the contrary, can be combined into larger groups. These systematic groups, or units, are called taxa.

The main taxonomic (systematic) unit is - species - Species. Species arose as a result of a long evolution of plants and each species has a certain area of ​​\u200b\u200bnatural distribution on earth - an area. Individuals of the same species have common morphophysiological, biochemical characteristics, are capable of interbreeding, giving fertile offspring in a number of generations (i.e., genetically compatible).

Each species belongs to a genus. Genus - Genus - a larger taxonomic unit, includes a group of closely related species that have many common features, for example, in the structure and arrangement of flowers, fruits and seeds. But there are also features: leaf pubescence, color of the corolla, shape or dissection of the leaf blade, etc.

The next larger taxonomic unit is the family - Familia, which combines close and related genera. Their affinity lies both in the structure of generative organs (flowers, fruits) and in the structure of vegetative organs (leaves, stems, etc.). The suffix -aceae is added to the end of the family. For example, the ranunculaceae family - Ranunculaceae, rosaceae - Rosaceae.

Similar families are combined into a larger group - the order - Ordo. Orders are combined into classes - Classis, and classes are combined into departments - Divisio or types. Departments make up the kingdom - Regnum.

If necessary, intermediate taxonomic units can also be used, for example, subspecies (subspeaes), subgenus (subgenus), subfamily (subfamilia), superorder (superordo), superkingdom (superreginum).

Taxonomic characteristics of the plant on the example of chamomile

Medicinal.

Systematics of lower and higher plants

lower plants

Whole vegetable world divided into two large groups: lower plants and higher plants.

lower plants- thallus, or thallus, have a body called thallus or thallus. These include pre-nuclear and nuclear organisms, the body of which is not divided into vegetative organs (root, stem, leaf), and does not have differentiated tissues. Among the lower plants there are unicellular, colonial and multicellular forms.

Prenuclear forms - Procaryota - do not have a membrane-limited nucleus, chloroplasts, mitochondria, Golgi complex and centrioles. The ribosomes are small, many have flagella, and the cell wall of many prokaryotes contains the glycopeptide murein. Mitosis and meiosis, as well as sexual reproduction, are absent, reproduction is carried out by cell division in two. Sometimes budding (yeast) occurs. Oxidative processes in many are represented by fermentations of various types (alcohol, acetic acid, etc.). Photosynthesis, if any, is associated with cell membranes. Many prokaryotes are capable of fixing atmospheric nitrogen; among them there are aerobes and anaerobes. Some prokaryotes form endospores, which contribute to the transfer of adverse environmental conditions.

Prokaryotes are apparently the first organisms to appear on Earth. Prokaryotes belong to the same kingdom of Drobyanok - Mychota, and it is divided into three sub-kingdoms: archaebacteria, true bacteria, oxyphotobacteria. The role of prokaryotes is enormous: they are involved in the accumulation of carbonates, iron ores, sulfides, silicon, phosphorites, bauxites. They process organic residues, participate in the production of many food products (kefir, cheese, koumiss), enzymes, alcohols, organic acids. With the help of biotechnology, antibiotics produced by bacteria, interferon, insulin, enzymes, etc. are obtained. This is the positive role of prokaryotes.

The lower plants include nuclear organisms - Eucaryota, whose cells have nuclei bounded by a membrane. Nuclear organisms include Fungi - Mycota (Fungi) and plants - Plantae (Vegetabilia).

Mushrooms - Mycota

Mushrooms are diverse in appearance, habitats, physiological functions, and size. Vegetative body - mycelium, consists of thin branching threads - hyphae. Fungi have a cell wall containing chitin, their reserve nutrient glycogen, and the mode of nutrition is heterotopic. Mushrooms are immobile in the vegetative state and have unlimited growth. In the protoplast of fungal cells, ribosomes, a nucleus, mitochondria are distinguishable; the Golgi complex is poorly developed. Fungi reproduce vegetatively (by parts of the mycelium), asexually (spores), and sexually (gametes).

Mushrooms also play a positive role in human life: they are widely eaten (porcini mushroom, boletus, boletus, milk mushrooms, etc.); yeast is used in fermentation processes (baking, brewing, etc.); many fungi form enzymes, organic acids, vitamins, antibiotics. A number of species (ergot, chaga) are used to obtain medicines

Plants - Plantae

Plants - Plantae - the kingdom of eukaryotic organisms, which are characterized by photosynthesis and dense cellulose membranes, the reserve nutrient is starch.

The plant kingdom is divided into three sub-kingdoms: scarlet (Rhodobionta), true algae (Phycobionta) and higher plants (Cormobionta).

At the first stage of classification, specialists divide organisms into separate groups that are characterized by a certain set of traits, and then arrange them in the correct sequence. Each of these groups in taxonomy is called a taxon (from the Greek taxon - (race) position, order). A taxon is the main object of taxonomy research, representing a group of zoological objects that actually exist in nature, which are sufficiently isolated, they can be distinguished and assigned a certain rank. Examples of taxa include such groups as "vertebrates", "mammals", "artiodactyls", "red deer" and others.

Taxon (lat. taxon, pl. taxa; from taxare- “to feel, to determine the price by feeling, to evaluate”) - a group in the classification, consisting of discrete objects, combined on the basis of common properties and signs.

In the International Code of Botanical Literature (Codex Vienna, 2006), the term "taxon" means a taxonomic group of any rank, it is understood that each plant is considered as belonging to an indefinite number of taxa of successively subordinate rank, among which the species rank is considered the main one. A taxon is defined similarly in zoology.

In modern biological classifications, taxa form a hierarchical system: each taxon, on the one hand, consists of one or more taxa of a lower level of generality, at the same time, each taxon is part of another taxon - a group of more high level community. Such a hierarchical system is called a taxonomic hierarchy, and its various levels are called taxonomic ranks.

The three most significant characteristics of a taxon in modern biological taxonomy are scope, diagnosis, and rank.

In the classification of the "father of taxonomy" by Carl Linnaeus, the taxa were arranged in the following hierarchical structure

Kingdom (Latin regnum) Animalia (animals)

Class (lat. classis) Mammalia (mammals)

Order (Squad) (Latin ordo) Primates (primates)

Genus (lat. genus) Homo (human)

View (lat. species) Homo sapiens (reasonable person)

Variety (Latin varietas)

The levels of this hierarchy are called ranks. Ranks (universal levels of hierarchy with their own names) were reflected in the classification at the end of the 17th century and since then, despite criticism from theoretical positions, have been an integral part of taxonomic practice. In connection with a much more detailed representation of systematic scientists about the structure biodiversity the number of ranks has increased significantly since the time of Linnaeus.

Taxon scope can be objectively specified by enumerating organisms (or taxa of lower rank). Often the volume of a taxon during historical development ideas about the system of a particular group is much more stable than its rank. So, liver mosses in different systems plants were considered either as a family, or as a department or class (in this case, only the rank of the group changed, but not its volume). Such taxa, in respect of which ideas of volume, but not of rank, have been established, are often referred to simply as "major groups".

Monophyly(ancient Greek μόνος - one and φυλή - family clan) - the origin of the taxon from one common ancestor. According to modern concepts, a group is called monophyletic in biological systematics, including all known descendants of a hypothetical closest ancestor, common only to members of this group and to no one else. In some groups of organisms, phylogenetic relationships have not been finally established.

It is now generally accepted that taxa must include descendants and all or some ancestors, although the validity of the latter requirement is increasingly subject to controversy. A natural taxon is one such group that is generated through the process of evolution. Such groups are monophyletic. An artificial taxon is the result of an old way of classifying (for example, by apparent similarity resulting from the evolution of dissimilar organisms), that is, such taxa are polyphyletic or paraphyletic.

One of the principles of systematics is the principle of hierarchy, or subordination. It is implemented as follows: closely related species are combined into genera, genera are combined into families, families into orders, orders into classes, classes into types, and types into a kingdom. The higher the rank of a taxonomic category, the fewer taxa of this level. For example, if there is only one kingdom, then there are already more than 20 types. The principle of hierarchy allows you to very accurately determine the position of a zoological object in the system of living organisms. An example is the systematic position of the white hare:

Kingdom Animals (Animalia) Type Chordata (Chordata)

Class Mammalia (Mammalia)

Order Hares (Lagomorpha) Family Hares (Leporidae) Genus Hares (Lepus)

In addition to the main taxonomic categories, zoological systematics also uses additional taxonomic categories, which are formed by adding the appropriate prefixes to the main taxonomic categories (supra-, sub-, infra-, and others) or auxiliary taxa (cohort, section).

The systematic position of the hare using additional taxonomic categories will be as follows:

Kingdom Animals (Animalia)

Subkingdom True multicellular (Eumetazoa) Type Chordata (Chordata)

Subtype Vertebrates (Invertebrata)

Superclass Tetrapoda (Tetrapoda)

Class Mammalia (Mammalia)

Subclass Viviparous (Theria)

Infraclass Placental (Eetheria)

Order Lagomorpha (Lagomorpha)

Family Hare (Leporidae)

Genus Hares (Lepus)

Species Hare (Lepus timidus)

Knowing the position of the animal in the system, one can characterize its external and internal structure, features of biology. So, from the above systematic position hare, you can get the following information about this species: it has a four-chambered heart, diaphragm and coat (features of the class Mammals); there are two pairs of incisors in the upper jaw, there are no sweat glands in the skin of the body (signs of the order Lagomorphs), ears are long, hind limbs are longer than the forelimbs (signs of the hare family), etc. This is an example of one of the main classification functions - prognostic (forecast function, prediction). In addition, the classification performs a heuristic (cognitive) function - it provides material for the reconstruction of animal evolutionary paths and an explanatory one - it demonstrates the results of studying animal taxa. To unify the work of taxonomists, there are rules that govern the process of describing new taxa of animals and assigning scientific names to them. These rules are collected in the International Code of Zoological Nomenclature, which is published by International Commission on zoological nomenclature, the latest 4th edition of the code came into force on January 1, 2000.

The history of the development of zoology is closely connected with the history of the formation of the basic principles of animal taxonomy. It would be impossible to understand all the diversity of the Earth's fauna without an apparatus that makes it possible to fix the position of the studied organisms on the phylogenetic tree of the animal kingdom. Such a device is modern taxonomy, which arose as a result of the painstaking work of many zoologists throughout the history of the development of science.

General principles:

- the assignment of a scientific name or concept.

- description.

- highlighting similarities and differences with similar concepts.

- classification.

- similarity of species.

The science of the diversity of plants, animals, fungi, microorganisms and their combination into groups (classifications) based on kinship is called taxonomy. Within this science, organisms are given names and grouped into groups, or taxa, based on certain relationships between them.

Taxon higher order - this is a kingdom (domain). Then comes the taxon called the kingdom, then for animals there are phylum, class, order, family, genus and species. When classifying plants, the same taxa are distinguished as in animals, but with slight differences. A taxon of the same rank as a type in animals is called a department, and a taxon called an order corresponds to an order. Different researchers distinguish from 4 to 26 different kingdoms, types - from 33 to 132, classes - from 100 to 200.

Plants Animals

Angiosperms Chordates

Dicot Mammals

Legumes Carnivores

Bean Bear

Clover Bear

Red clover Brown bear

Biological nomenclature based on the binomial system proposed in the 16th century. K. Linnaeus (the name of each organism consists of two words, the first denotes the genus, the second the species). generic the name is capitalized specific- with a small one: Betula alba - birch (genus name) white (species name); Viola tricolor - tricolor violet; Homo sapiens is a reasonable person.

Human:

chordate type,

vertebrate subphylum,

class Mammals,

subclass placental,

primate squad,

suborder higher apes,

human family,

kind of people.

Evolution of the organic world:

The modern system of the organic world:

Empire Empire

Noncellular Cellular

super-kingdom super-kingdom

Prokaryotes Eukaryotes

kingdom kingdom kingdom kingdom kingdom kingdom

Viruses Bacteria Archaea Animals Fungi Plants

Thematic tasks

A1. The main struggle for existence takes place between

1) classes

2) departments

3) families

A2. The area is the area of ​​distribution

3) kingdoms

AZ. Specify correct order classification

1) class - type - family - detachment - species - genus

2) type - class - order - family - genus - species

3) detachment - family - genus - species - department

4) species - genus - type - class - detachment - kingdom

A4. Specify the sign on the basis of which two finches can be attributed to different species.

1) live on different islands

2) differ in size

3) bring fertile offspring

4) differ in chromosome sets

A5. Which of the taxonomic groups of plants is indicated incorrectly?

1) class dicot

2) department of angiosperms

3) conifer type

4) cruciferous family

A6. The lancelet belongs to

1) chordate class

2) subclass of fish

3) type of animals

4) subtype of non-cranial

A7. Cabbage and radish belong to the same family based on

1) the structure of the root system

2) leaf venation

3) stem structures

4) the structure of the flower and fruit

A8. In which case are the "kingdoms" of the organic world listed?

1) bacteria, plants, fungi, animals

2) trees, predators, protozoa, algae

3) invertebrates, vertebrates, chlorophyll

4) spore, seed, reptiles, amphibians

IN 1. Choose three titles families plants

1) dicot

2) bryophytes

5) moth

6) rosaceous

IN 2. Choose three animal order names

2) reptiles

3) cartilaginous fish

5) tailless (amphibians)

6) crocodiles

VZ. Establish the sequence of subordination of systematic groups of plants, starting with the largest

A) Department of Angiosperms

B) family Cereals

B) awnless wheat species

D) genus Wheat

D) class Monocots