Data for download – species and traits

Plant heights are relevant for the Czech Republic. They are measured in metres and relate to fully developed mature generative plants growing in the wild. Each taxon is characterized by two values: minimum (lower limit of the common range) and maximum (upper limit of the common range). The data were taken from the Key to the Flora of the Czech Republic (Kaplan et al. 2019).

Data source and citation

Kaplan Z., Danihelka J., Chrtek J. Jr., Kirschner J., Kubát K., Štěpánek J. & Štech M. (eds) (2019) Klíč ke květeně České republiky [Key to the flora of the Czech Republic]. Ed. 2. – Academia, Praha.

Life form classification follows the system of Raunkiaer (1934), which is based on the position of the buds that survive the unfavourable season. Macrophanerophytes are woody plants that bear the surviving buds at least 2 m above the ground, usually trees; nanophanerophytes are woody plants with surviving buds 0.3–2 m above the ground, usually shrubs; chamaephytes are herbs or low woody plants with surviving buds above the ground, but not more than 30 cm above it; hemicryptophytes are perennial or biennial herbs with surviving buds on aboveground shoots at the level of the ground; geophytes are perennial plants with surviving buds belowground, usually with bulbs, tubers or rhizomes; hydrophytes are plants with surviving buds in water, usually on the bottom of water bodies; therophytes are summer- or winter-annual herbs that survive the unfavourable season only as seeds germinating in autumn, winter or spring.

The data on life forms were taken from the Key to the Flora of the Czech Republic (Kaplan et al. 2019). Newly added alien taxa were assigned to the categories of life forms based on the FloraVeg.EU database (Dřevojan et al. 2022). Some taxa can belong to more than one life form. In such cases, the dominant life form is listed first.

Category

• macrophanerophyte
• nanophanerophyte
• chamaephyte
• hemicryptophyte
• geophyte
• hydrophyte
• therophyte

Data source and citation

Kaplan Z., Danihelka J., Chrtek J. Jr., Kirschner J., Kubát K., Štěpánek J. & Štech M. (eds) (2019) Klíč ke květeně České republiky [Key to the flora of the Czech Republic]. Ed. 2. – Academia, Praha.

Further references

Dřevojan P., Čeplová N., Štěpánková P. & Axmanová I. (2022) Life form. – www.FloraVeg.EU.
Raunkiaer C. (1934) The life forms of plants and statistical plant geography. – Clarendon Press, Oxford.

Diaspore, also called dispersule or propagule, is a generative or vegetative part of the plant body that is dispersed from the parental plant and can produce a new individual. Generative diaspores include spores, seeds and fruits or similar dispersal units (e.g. aggregate fruits in Fragaria, multiple fruits in Morus, gymnosperm cones, epimatium-bearing seed in Taxus, spikelets or their various fragments in Poaceae). If the seed is released from dehiscent fruit or decaying ripe fleshy fruit, both seed and fruit can be considered as diaspores. In plants with indehiscent fruits, only the fruit is considered as a diaspore. A specific category of generative diaspore is tumbleweeds, i.e. mature plant parts including stem branches and large inflorescence (e.g. Crambe tataria and Falcaria vulgaris).

Vegetative diaspores are viable and movable parts of plants that originate above ground or in water and disconnect from the parent plant before sprouting. We did not consider as vegetative diaspores clonal organs connected with the maternal plant until the new plant becomes independent (e.g. stolons in Fragaria) and various types of below-ground organs or shoot bases embedded in soil (e.g. tubers of Helianthus tuberosus or grass tillers). Vegetative diaspores include (i) turions (e.g. Myriophyllum and Utricularia) and similar overwintering structures (detachable buds in Elodea and Groenlandia and shortened shoots of some pondweeds produced by rhizome or stolon, e.g. Potamogeton alpinus); (ii) bulbils and tubers of stem origin (e.g. Allium oleraceum and Dentaria bulbifera) or root origin (Ficaria only); (iii) plantlets born by pseudovivipary (e.g. Poa alpina); (iv) plantlets born from buds on leaves (e.g. Cardamine pratensis); (v) plantlets born on free ends of stolons, detachable before establishing (e.g. Hydrocharis and Jovibarba); (vi) unspecialized fragments of the shoot (e.g. Sedum album and many aquatic plants), shoot tips (e.g. Ceratophyllum demersum) or detachable offsprings born from axillary buds (e.g. Agrostis canina, Arabidopsis halleri and Rorippa amphibia); (vii) budding plants (Lemnaceae only); and (viii) gemmae produced by gametophytes (Trichomanes speciosum only).

Category

• spore
• seed
• fruit, infrutescence or its part
• tumbleweed
• turion
• bulbil or tuber
• pseudovivipary
• leaf-born plantlet
• stolon-born plantlet
• shoot fragment
• budding
• gametophyte-gemma

Data source and citation

Sádlo J., Chytrý M., Pergl J. & Pyšek P. (2018) Plant dispersal strategies: a new classification based on themultiple dispersal modes of individual species. – Preslia 90: 1–22.

Plants use different dispersal modes, also called dispersal syndromes, depending on different dispersal vectors. For example, anemochory is the dispersal by wind, hydrochory by water, epizoochory by attachment to an animal body and endozoochory by animals via ingestion. However, single plant species usually use a combination of several dispersal modes rather than a single mode. Distinct combinations of dispersal modes repeatedly occurring in different plant taxa are called dispersal strategies. Sádlo et al. (2018) distinguished nine dispersal strategies named for the genus names of typical representatives. Taxa of the Czech flora are assigned to individual strategies based on this source.

Categories

• Allium type – mainly autochory, less frequently anemochory, endozoochory and epizoochory. This is the most common dispersal strategy, including about 56% taxa of the Czech flora. About half of the included taxa are dispersal generalists lacking a clear morphological indication of anemochory or zoochory. Most myrmecochorous or probably myrmecochorous species are also assigned to this category.
• Bidens type – mainly autochory and epizoochory, less frequently endozoochory. This dispersal strategy is characterized by two essential dispersal modes, of which autochory is the more important, despite the presence of morphological structures indicating epizoochory.
• Cornus type – mainly autochory and endozoochory. Herbaceous plants, shrubs and small trees with fleshy fruit, often of the Rosaceae family, typically have this strategy. Furthermore, tall trees bearing large, heavy and nutrient-rich seeds are also included.
• Epilobium type – mainly anemochory and autochory, less frequently endozoochory and epizoochory. This dispersal strategy is typical of taxa growing in mesic and dry habitats.
• Lycopodium type – mainly anemochory, less frequently autochory, endozoochory, epizoochory and hydrochory. This dispersal strategy relies on light, very small spores and seeds that are dispersed, besides wind, by a wide range of vectors. Compared to other strategies, the role of autochory is small.
• Phragmites type – mainly anemochory and hydrochory, less frequently autochory, endozoochory and epizoochory. Wetland taxa with light diaspores (both seeds and fruits) equipped with a hairy flying apparatus. Most of the taxa with this dispersal strategy lack vegetative diaspores. Woody plants, stout clonal graminoids and herbaceous plants are typical growth forms associated with this dispersal strategy.
• Sparganium type – mainly autochory and hydrochory, less frequently endozoochory and epizoochory. This dispersal strategy is a wetland analogue of the Wolffia type, assigned to aquatic plants. It applies mainly to monocotyledonous taxa producing achenes with good buoyancy and with vegetative diaspores having an important role.
• Wolffia type – mainly hydrochory, less frequently endozoochory and epizoochory. This dispersal strategy is typical of aquatic macrophytes spread by fruit, seed or spores. However, vegetative reproduction dominates in most cases, including stem fragmentation, the formation of stolons or, in Lemnaceae, budding colonies.
• Zea type. Taxa with this dispersal strategy rarely or never disperse by generative diaspores and do not form vegetative aboveground diaspores.

Category

• Allium (mainly autochory)
• Bidens (mainly autochory and epizoochory)
• Cornus (mainly autochory and endozoochory)
• Epilobium (mainly anemochory and autochory)
• Lycopodium (mainly anemochory)
• Phragmites (mainly anemochory and hydrochory)
• Sparganium (mainly autochory and hydrochory)
• Wolffia (mainly hydrochory)
• Zea (no dispersal)

Data source and citation

Sádlo J., Chytrý M., Pergl J. & Pyšek P. (2018) Plant dispersal strategies: a new classification based on themultiple dispersal modes of individual species. – Preslia 90: 1–22.

The type of clonal growth is only reported for clonal herbs. Clonal growth is defined here as the growth of the plant body leading to the formation of physically independent asexual offspring. A morphological prerequisite for clonal growth is the formation of adventitious roots on stems or adventitious shoots from root buds that yield (potentially) physically independent individuals (Groff & Kaplan 1988). The types of clonal growth organs are morphological categories that are defined based on three main parameters:

1. Bud-bearing organ that gives rise to the clonal growth organ (shoot or root)
2. Position of the organ relative to the soil surface (aboveground, belowground, initially aboveground and later belowground, water)
3. Storage organ (shoot, root, leaf)

For each taxon, only one type of the clonal growth organ is reported, although some taxa possess several independent types of such organs (Klimešová & Klimeš 2006). The reported type is considered as the most important for the life cycle of the taxon, producing the highest number of offspring or permitting the individual to spread its offspring over large distances. Some of these types are vegetative diaspores, while others are used for local spread but not long-distance dispersal. The clonal growth organs are divided into aboveground and belowground and sorted within each category by their decreasing frequency in the Czech flora.

Categories

Aboveground organs

• stolon – a horizontal aboveground shoot rooting in the soil and providing connection between offspring plants and the mother plant or formed by a creeping main shoot
• turion – a detachable over-wintering bud of aquatic plants composed of tightly arranged leaves filled by storage compounds
• stem fragment – a detached part of the shoot with rooting ability
• budding plant – an extremely reduced body of aquatic plants formed by a small frond (e.g. Lemna)

Belowground organs

• epigeogenous rhizome – a perennial clonal organ of stem origin growing horizontally at the soil surface; its distal part is covered by soil and litter or pulled into the soil by the contraction of roots; nodes bear green leaves, the internodes are usually short
• hypogeogenous rhizome – a perennial clonal organ of stem origin usually growing horizontally at a species-specific depth belowground; after some time its tip turns up, becoming orthotropic and forming aboveground shoots; the horizontal part of the rhizome has long internodes and bears bracts and roots (usually only on the nodes)
• belowground stem tuber – a belowground, usually short-lived storage and regenerative organ of shoot origin
• bulb – a storage organ consisting of storage leaves and a shortened stem base
• root with adventitious buds – primary root including the hypocotyl or adventitious root forming adventitious buds spontaneously or after an injury
• root tuber – a belowground storage organ of root origin growing from a bud-bearing stem
• stolon with tuber – a stolon with a belowground, usually short-lived storage and regenerative organ developing at its distal end

Category

• stolon
• turion
• stem fragment
• budding plant
• epigeogenous rhizome
• hypogeogenous rhizome
• belowground stem tuber
• bulb
• root with adventitious buds
• root tuber
• stolon with tuber

Data source and citation

Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

Further references

Groff P. A. & Kaplan D. R. (1988) The relation of root systems to shoot systems in vascular plants. – Botanical Review 54: 387–422.

This trait is defined only for clonal herbs. Clonality of herbs can be realized by the formation of freely dispersible clonal offspring, i.e. new individuals that are separated from the mother shoots very shortly after their formation and before they develop roots attaching them to the soil. They are dispersed by water or other agents. Typical examples are plantlets, bulbils, turions or stem fragments of aquatic plants. The data reported here are based on individual observations in the CLO-PLA 3.4 database (Klimešová & Klimeš 2006, Klimešová et al. 2017).

Categories

• přítomno
• chybí

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

This trait, defined for herbs, is measured as the number of years from the emergence of the aboveground part of the shoot till its flowering and fruiting (Serebryakov 1952). Based on the analysis of morphological traits, we distinguish shoots with cyclicity of one year (monocyclic) from those that live longer (di- and polycyclic). In plants with sympodial branching, cyclicity refers to all shoots, while in plants with monopodial branching, it refers only to flowering shoots, although flowering and sterile shoots can be present simultaneously. Monocyclic plants usually do not possess a leaf rosette, and all shoots in a population can flower. In contrast, di- and polycyclic shoots possess a basal leaf rosette and shoot populations contain flowering and sterile shoots at the same time.

The data are based on individual observations in the CLO-PLA 3.4 database (Klimešová & Klimeš 2006). If more types are reported for one taxon, the most frequently observed type is given (Klimešová et al. 2017).

Category

• monocyclic shoots prevailing
• dicyclic or polycyclic shoots prevailing

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

Further references

Serebryakov I. G. (1952) Morfologiya vegetativnykh organov vysshikh rastenii [Morphology of vegetative organs of higher plants]. – Sovetskaya nauka, Moskva.

Branching type is defined for clonal herbs. It determines whether individuals possess two different shoot types (flowering and sterile) or only one shoot type (which can potentially flower). In plants with sympodial branching, all shoots are identical in their construction, replacing each other during ontogeny of the individual; all of them can potentially flower. In contrast, plants with monopodial branching possess two shoot types, one of which never flowers, whereas the flowering shoots arise from axillary buds of the non-flowering shoot. Finally, ferns and lycophytes can possess dichotomous branching that is functionally similar to monopodial branching.

The data reported here are based on individual observations in the CLO-PLA 3.4 database (Klimešová & Klimeš 2006). If more types are reported for one taxon, the most frequently observed type is given here (Klimešová et al. 2017).

Category

• monopodial
• sympodial
• dichotomous

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

The presence of the primary root is only defined for herbs. The primary root can be either present for the whole life of a plant or replaced during the ontogeny by adventitious roots. If the primary root is the only root for the whole life of a plant, the plant is not capable of forming adventitious roots on stems; therefore it is not clonal (unless it is able to form adventitious buds on roots; Groff & Kaplan 1988). In contrast, if the primary root is existing only in an early ontogenetic stage and later replaced by adventitious roots formed on belowground parts of the stem, the plant can grow clonally. In older individuals of some taxa that preserve the primary root, this root can split into parts, giving rise to several independent plant individuals. Some taxa only form adventitious roots under specific conditions (soil moisture, root injury or old age).

The data reported here are based on individual observations stored in the CLO-PLA 3.4 database (Klimešová & Klimeš 2006). If more types are reported for one taxon, the most frequently observed type is given (Klimešová et al. 2017).

Categories

• přítomen
• chybí

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

Further references

Groff P. A. & Kaplan D. R. (1988) The relation of root systems to shoot systems in vascular plants. – Botanical Review 54: 387–422.

Persistence of the clonal growth organ, defined for clonal herbs, determines the life span of the physical connection between the parent and offspring shoots. Because morphological analysis does not permit the identification of such life span beyond a period of few years, the persistence of the connection is assessed in categories (< 1, 1–2, > 2 years; Klimešová & Klimeš 2006). From those categories, mean values of their ranges (0.5, 1.5 and 4 years) are used, and the final value is the mean of all records for the given taxon and the given type of the clonal growth organ in the CLO-PLA 3.4 database (Klimešová et al. 2017).

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

This trait is only defined for clonal herbs. The number of offspring shoots produced per parent shoot of a clonal herb per year is estimated in categories (< 1, 1, 2–10, > 10; Klimešová & Klimeš 2006), which are represented by the mean values of their ranges (0.5, 1, 6, and 15). The reported value is the mean of these values across all the available measurements for individuals of the given taxon and type of clonal growth organ in the CLO-PLA 3.4 database (Klimešová et al. 2017).

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

The lateral spreading distance by clonal growth is defined for clonal herbs as the distance between parental and offspring shoots. Freely dispersible vegetative diaspores are not considered. Lateral spreading distances were estimated in categories (< 0.01 m, 0.01–0.25 m, > 0.25 m; Klimešová & Klimeš 2006), which are represented by the mean values of their ranges (0.005 m, 0.13 m, 0.5 m). The reported value is the mean of these values across all records for the given taxon and the given type of clonal growth organ in the CLO-PLA 3.4 database (Klimešová et al. 2017).

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

The Clonal index (Johansson et al. 2011) is a measure of taxon’s clonal ability. It is defined for clonal herbs as the sum of the ranks of the four categories of “Number of clonal offspring” (coded as 1, 2, 3, 4) and the three categories of “Lateral spreading distance by clonal growth” (coded as 1, 2, 3) with the presence of freely dispersible vegetative diaspores added as the fourth category (4). The index values range from 2 to 8, with higher values indicating better clonal ability. The index is defined for clonal herbs.

The data reported here are based on the categories of “Number of clonal offspring” and “Lateral spreading distance by clonal growth” aggregated from individual records in the CLO-PLA 3.4 database (Klimešová & Klimeš 2006, Klimešová et al. 2017).

Data source and citation

Klimešová J., Danihelka J., Chrtek J., de Bello F. & Herben T. (2017) CLO-PLA: a database of clonal and budbank traits of the Central European flora. – Ecology 98: 1179.
Klimešová J. & Klimeš L. (2006) CLO-PLA3: a database of clonal growth architecture of Central-European plants. – http://clopla.butbn.cas.cz.

Further references

Johansson V. A., Cousins S. A. O. & Eriksson O. (2011) Remnant populations and plant functional traits in abandoned semi-natural grasslands. – Folia Geobotanica 46: 165–179.

In contrast to stem buds, which are always located in a leaf axil, adventitious buds on roots (or hypocotyl) are not located at specific positions of the roots. They occur only in some root types or may only appear after the individual is injured. Root buds are found in approximately 10% of species in the Czech flora. Adventitious buds may be located on the hypocotyl, on the primary root, or on lateral roots. We list the hypocotyl only if the roots are found exclusively on it. We report the primary root if the buds are never formed on lateral roots, and we report the lateral roots if root buds are potentially found on all three types of bud-bearing organs. The data were taken from Bartušková et al. (2017).

Category

• hypocotyl
• primary root
• lateral roots

Data source and citation

Bartušková A., Malíková L. & Klimešová J. (2017) Checklist of root-sprouters in the Czech flora: mapping the gaps in our knowledge. – Folia Geobotanica 52: 337–343.

Adventitious buds on roots or hypocotyl occur in only about 10% species of the Czech flora and have different roles in individual taxa. In some taxa, they occur only after the plant is injured and play a role in regeneration after such injury (regenerative role). In other taxa, these buds are formed without such an external stimulus. Consequently, they increase the number of shoots and thereby the number of offspring, both clonally and by seed. In most taxa, such buds occur only in some individuals and are not necessary for completing the life cycle; we denote them as additive (or accessory) root buds. In a few taxa, the formation of root buds is necessary for completing the life cycle and flowering. They develop in all individuals, and survival/flowering or overwintering of an individual is dependent on them (Rauh 1937, Klimešová 2007). The data were taken from Bartušková et al. (2017).

Category

• regenerative
• additive
• necessary

Data source and citation

Bartušková A., Malíková L. & Klimešová J. (2017) Checklist of root-sprouters in the Czech flora: mapping the gaps in our knowledge. – Folia Geobotanica 52: 337–343.

Further references

Klimešová J. (2007) Root-sprouting in myco-heterotrophic plants: prepackaged symbioses or overcoming meristem limitation? – New Phytologist 173: 8–10.
Rauh W. (1937) Die Bildung von Hypocotyl- und Wurzelsprossen und ihre Bedeutung für die Wuchsformen der Pflanzen. – Acta Nova Leopoldina 4/24: 395–555.

National Red List categories were taken from the 2017 edition of the Red List of Vascular Plants of the Czech Republic (Grulich 2017). These categories, introduced in the previous editions of the Czech Red List, are different from the IUCN Red List categories. The main category “A” includes extinct or missing taxa, while the main category “C” includes endangered, near threatened and data deficient taxa.

Category

• A1 – extinct taxon
• A2 – missing taxon
• A3 – extinct or missing taxon (uncertain case)
• C1r – critically threatened taxon, rare
• C1t – critically threatened taxon, declining
• C1b – critically threatened taxon, rare and declining
• C2r – endangered taxon, rare
• C2t – endangered taxon, declining
• C2b – endangered taxon, rare and declining
• C3 – vulnerable taxon
• C4a – near threatened taxon
• C4b – data deficient taxon
• taxon is not on the Red List

Data source and citation

Grulich V. (2017) Červený seznam cévnatých rostlin ČR [The Red List of vascular plants of the Czech Republic]. – Příroda 35: 75–132.

International Red List categories defined by the IUCN were taken from the 2017 edition of the Red List of Vascular Plants of the Czech Republic (Grulich 2017). Taxon assignments to these categories follow the internationally accepted rules (IUCN 2012, 2014). To some extent, the definitions of these categories differ from the national categories used in the previous Czech Red Lists. The national Red List included only threatened or possibly threatened taxa, implying that the non-included taxa are not threatened. Therefore, the non-included taxa are classified here as LC(NA) – least concern (taxon is not on the Red List).

Category

• EX – extinct
• RE – regionally extinct
• CR – critically endangered
• EN – endangered
• VU – vulnerable
• NT – near threatened
• LC – least concern
• LC(NA) – least concern (taxon is not on the Red List)
• DD – data deficient
• NA – not applicable
• NE – not evaluated

Data source and citation

Grulich V. (2017) Červený seznam cévnatých rostlin ČR [The Red List of vascular plants of the Czech Republic]. – Příroda 35: 75–132.

Further references

IUCN (2012) Guidelines for application of IUCN Red List criteria at regional and national levels. Version 4.0. – IUCN, Gland.
IUCN (2014) Guidelines for using the IUCN Red List categories and criteria. Version 11. – IUCN, Gland.

Legal protection in the Czech Republic concerns the specifically protected species, i.e. rare taxa, threatened taxa and taxa significant from a cultural or scientific point of view that are listed in Annex II of the Decree of the Ministry of the Environment no. 395/1992. They comprise 487 taxa of vascular plants divided into three categories according to their vulnerability: critically threatened, endangered and vulnerable.

Category

• critically threatened taxon
• endangered taxon
• vulnerable taxon
• not protected by law

Data source and citation

Decree no. 395/1992 of the Ministry of the Environment of the Czech Republic.

The categories follow the third edition of the Red List of vascular plants of the Czech Republic (Grulich 2012). These categories, introduced in the previous editions of the Red List, do not accurately match the IUCN Red List categories. The main category A includes extinct or missing taxa, while the main category C includes endangered, near threatened and data deficient taxa.

Category

• A1 – extinct taxon
• A2 – missing taxon
• A3 – extinct or missing taxon (uncertain case)
• C1r – critically threatened taxon, rare
• C1t – critically threatened taxon, declining
• C1b – critically threatened taxon, rare and declining
• C2r – endangered taxon, rare
• C2t – endangered taxon, declining
• C2b – endangered taxon, rare and declining
• C3 – vulnerable taxon
• C4a – near threatened taxon
• C4b – data deficient taxon
• taxon is not on the Red List

Data source and citation

Grulich V. (2012) Red List of vascular plants of the Czech Republic: 3rd edition. – Preslia 84: 631–645.