Salsola tragus

Salsola tragus, often known by its synonym is a species of flowering plant in the family Amaranthaceae. It is known by various common names such as  prickly Russian thistle, windwitch, or common saltwort. It is widely known simply as tumbleweed because, in many regions of the United States, it is the most common and most conspicuous plant species that produces tumbleweeds. Informally, it may be known as "'Kali or Salsola": the latter being its restored genus, containing 54 other species, into which the obsolete genus Kali has been subsumed.

For a brief phase during its youth, it may be grazed but afterward becomes too spiny and woody to be edible to most wildlife and livestock (if it is not processed first). Mature specimens are often more than a meter in diameter. As its fruits mature, the diaspore of the plant dies, dries, hardens, and detaches from its root. This detached anatomical part of is colloquially called "tumbleweed" (although there are many other plant species that also produce tumbleweeds). Once mature, dry, and detached from the plant, this tumbleweed will tumble (i.e., roll) due to the force of the wind. As this dead structure tumbles in the wind, it gradually degrades and falls apart, thereby spreading possibly as many as 200,000 seeds. If it happens to come to rest in a wet area then it can germinate rapidly, even with very small amounts of moisture. It has a high tolerance of salinity and can successfully compete with many native plants in certain environments, such as along sea beaches and especially in grassland, desert, or semiarid regions. Consequently, it now occupies a wide variety of habitats. Native to Eurasia, has proven to be highly invasive as an introduced species and rapidly became a common ruderal weed of disturbed habitats throughout the world. The tumbleweed's tumbling is known to damage non-native plants and environments and its highly flammable nature also sometimes helps wildfires spread, especially during windy conditions. An ignited tumbleweed may spread a fire across firebreaks and may even ignite buildings or structures that it stops against.

Taxonomy
Linnaeus originally described the species as ; it is native to Eurasia, but in the 1870s, it appeared in South Dakota when flaxseed from Russia turned out to be contaminated with seeds. Although it is the best-known of this group of weeds and was at first thought to be a single well-defined species, it now is known to have included more than one species plus some hybrids. This has led to taxonomic confusion in dealing with species in the genera and  in America. Recent studies show that the population that once was assigned to includes three or more morphologically similar species that differ in flower size and shape. The group was widely assigned to the family Chenopodiaceae, but the Chenopodiaceae – including the genera and  – have since been included in the Amaranthaceae. They now are allocated to the Salsoloideae, a subfamily of the Amaranthaceae.

Description
is an annual forb. In habit, the young plant is erect, but it grows into a rounded clump of branched, tangled stems, each one up to about a metre long. Depending on the plant's genetics and condition, the leaves and stems may be green, red, or striped, and they may be hairless or pubescent. The leaves are tipped with spines that in most varieties are so sharp that the plants are best handled with gloves and other suitably protective clothing, though some genetic variants have only a hair at the tip. On the young plant, leaves may be more than 5 cm long, succulent and more or less cylindrical; these juvenile leaves are deciduous and drop off as the plant matures. The leaves of the mature plant are persistent, leathery, broader and shorter than the young leaves (seldom more than 1 cm in length), rigid and spine-tipped. They remain on the stem till the plant dies at the end of the season. In the axil of the mature leaf, there are two leaf-like bracts with a flower between them. The flower lacks petals, but is surrounded by a disk of wide, winged sepals, whitish to pink in color.

Reproduction and dispersal
The plant becomes woody as the fruits develop. As they ripen, the plant begins to die, dries out and becomes brittle. In that state the base of the stem breaks off easily, particularly in a high wind. The plant then rolls readily before the wind and disperses its seeds as a tumbleweed.

A large specimen of may produce some 200,000 seeds.

Invasive potential
has proven to be highly invasive as an introduced species and rapidly became a common ruderal weed of disturbed habitats in many regions of North America, particularly in the Midwest. The species also has become naturalized in various regions of Central and South America and in parts of Southern Africa and Australia. It now occupies a wide variety of habitat types in those regions and often is the first or even the only colonizer in conditions where no local species can compete successfully. Because of its preference for sand and its tolerance of salinity, it commonly grows along sea beaches as well as in disturbed grassland and desert communities, especially in semiarid regions.

Edibility
The plant is considered edible when young, and the young shoots can be harvested and eaten. As the plant matures, it becomes too woody, bitter, and spiny to be considered edible. The young shoots can be eaten raw in salads, and are reported to be even more flavorful when cooked as a pot herb. Young plants are also reported as good fodder for livestock. Some varieties of Russian thistle can contain above average levels of oxalic acid, particularly in older plants, and people who are sensitive to oxalic acid should avoid the genus as it is a severe allergen for some people. Oxalates in certain vegetables contribute to gout and are a causative agent in certain types of kidney stones and bladder stones, therefore K. tragus is not recommended for people with a history of such conditions or whom have diabetic kidney disease. People who have adverse reactions to eating spinach, which also can have high levels of oxalates, should avoid consumption of Russian thistle.

Ecology and agricultural management
is a ruderal annual forb. It germinates rapidly even in very small amounts of moisture in arid conditions. When young it may be grazed freely, but that phase lasts for only a brief period, and generally at a time when other forage is relatively plentiful. After this it becomes a weed in most contexts. One reason is that as they mature most varieties become too spiny and woody for most stock to browse. Moreover older foliage develops higher levels of oxalates, bitter tannins and alkaloids making it unpalatable. As its fruits mature, the plant dies, dries and becomes hard and brittle. It is in this state that it is likely to detach from its root and become a tumbleweed. As tumbleweeds go, it is very large, often a metre or more in diameter, spiny, largely inedible to most livestock if unprocessed, and a fire hazard. However, in regions where there is plentiful winter rain, the moisture softens both the twigs and the spines, after which hardy breeds of livestock and some wildlife species once again will eat it.

has acquired a bad reputation for its spininess, its woodiness when mature, and its general ecological competitiveness, augmented by its tumbleweed nature, which enables it to spread rapidly over open ground. Prince Gallitzin reported that on the journey out of his native Russia he passed through southwest Siberia and found the Imperial government's irrigation project abandoned and the farms deserted, on account of K. tragus. Furthermore Oryol Oblast and Kyiv Oblast were also especially infested. During the past century or more, the majority of the publications that dealt with the topic have discussed its pernicious nature, the increasing threats that the species poses, and how to combat its invasiveness; they largely have ignored its other attributes.

However, even early publications did concede that the plant is of value as a forage in severely arid conditions where few other forage species are viable. As for its harmful competitiveness, most authors emphasised its invasiveness, though some did mention its value in regenerating overgrazed or otherwise abused land.

Apart from its value to domestic cattle and sheep in some regions, is a source of food and shelter for several species of wild life. Its nutritional value is high; it is rich in various minerals, Vitamin A, and phosphorus. It is a minor forage component for bison, mule deer, and wapiti. Pronghorn eat it with reluctance in drought conditions, but feed on it avidly under rainy conditions, especially in wet years. Prairie dogs consume it as a major food wherever they encounter it. Seed-eating birds and small mammals such as rodents feed on the seeds.

offers shelter for some wildlife. Medium-sized deer species make some use of it, but it is mainly of value to small mammals and bird species that normally live close to the ground and shelter under bushes.

Some livestock species such as camels and some breeds of stock that are adapted to semi-desert conditions will brave the spines when forage becomes scarce. Many goats and some breeds of sheep such as karakul browse the bushes. The plant, like many members of the Amaranthaceae, is rich in high-quality proteins with a good balance of essential amino acids, the seed even more so.

Oxalic acid occurs in a wide range of plants including S. tragus as an adaptation to alkaline, relatively drier soils rich in calcite, gypsum, alumina, and/or other metal ions. Oxalic acid forms highly insoluble salts with calcium, aluminum, chromium, copper, lead, and many other transition metals. Oxalic acid is produced in specialized parenchyma cells called Idioblasts. There it binds with excess calcium from plant tissue forming needle-like crystals of calcium oxalate monohydrate inside such cells, called Raphides. Calcium along with other metal ions are sequestered in idioblast cells, reducing their impact on the rest of the plant's tissues. Rhaphides also serve as a deterrent against insect predators, as the sharp crystal injure an insect's digestive tract.

and many related species, including some that are widely regarded as invasive weeds in other countries, are valued in their regions of origin. They are adapted to inhospitable environments that do not support many other forage species. In Uzbekistan, for example, stems, fruits, and leaves are nutritious year-round camel feed; sheep and goats prefer it in summer, but also to some extent in autumn and winter. The fruits are important for fattening camels, goats, and karakul sheep; the fruit may partially substitute for concentrates, especially in autumn and winter. In those regions annual species are known as "solyanki"; they are important as drought- and salt-tolerant forage and form a dominant group in the flora and vegetation of the most challenging environments. Some are useful for stabilising shifting sands and for rehabilitation of degraded rangelands such as the saline soil of the red desert of Kyzyl Kum. Some of the species also invade ruderal sites or occur as weeds in cultivated fields.

Although still has not won much recognition in contemporary first-world livestock nutrition, this might reflect short memories rather than shortage of evidence for its merits; during the Dust Bowl era, it was credited with having rescued beef cattle husbandry in North America. The usual hay crops had failed and when all other sources failed farmers fed their cattle on tumbleweed.

Salsola management and soil rehabilitation
In spite of the reigning conception that its presence is harmful, is of particular value in rehabilitating certain classes of disturbed land. Often its presence is beneficial, especially when the original topsoil still is present; the species happens not to be host to any mycorrhizal fungi, whereas many or most common plants in fact are so adapted. As a result, when mycorrhizae surviving in the topsoil invade roots they tend to kill the tissue, commonly stunting or even killing the plant. When the plant is dead and the mycorrhizae have consumed what they can of its remains, they spread out and infect more plants, beneficially to most desirable grasses and forbs, but to the disadvantage of most of the that had been occupying the soil. They only remain to enrich, mulch and aerate it. This promotes reinvasion of the soil by other plants adapted to forming advantageous symbiotic associations with mycorrhizae. Above the ground, any dead plants that remain standing provide shade that favours other plants' seedlings; the plants themselves on the other hand are highly intolerant of shade, being very much adapted to open, barren soil. This apparently complex process tends to repopulate the soil better and faster than killing the with herbicides and waiting for apparently more desirable plants to make good the original damage to the soil.

In disturbed sites with no topsoil and therefore few or no mycorrhizae, the population may remain dominant for over a decade. To speed the recovery, it is better to add rich topsoil with plenty of organic material and mycorrhizae than to attack the population. However, it is important not to regard the ecological interrelationships too simplistically; in some cases the presence of the healthy weed plants on a harsh site without mycorrhizae actually seems to facilitate the succession of grass better than where a mycorrhizal inoculum had reduced the population of the. The assumed competitive effect of the should be assessed and monitored in each case. Furthermore, of course, where degraded soil is effectively barren, is better as a pioneer population than simply leaving the soil completely barren. grows best on sandy or at least loose-surfaced soil, so it might pay better to rake the soil to encourage plant growth for a few years until its presence has mitigated the conditions.

Another factor to bear in mind in dealing with is grazing or, more particularly, overgrazing. In regions where competitive vegetation is present together with the, overgrazing may favour the weed, while managing the grazing intensity to favour the desired plants may be the most economical, and in the long term, the most effective way of dealing with its overgrowth. A good example was in controlling troublesome on Bighorn Sheep Winter Ranges in Jasper National Park by proper management of grazing intensity.

Salsola and phytoremediation
A special class of soil mitigation is phytoremediation, in which the removal and accumulation of toxic elements from soils by suitable management of plant growth is a major component. Because such soil situations as mine dumps tend to be extreme examples of disturbed sites, and often are of fine texture, species show promise for certain classes of such work. Simply by growing there in high density they can play a valuable role in phytostabilization by reducing wind erosion and similar processes that promote the spread of pollution. The dry tumbleweed material also has been used as a mulch on replanted coal mine spoils in Arizona.

However, these plants also show promise as hyperaccumulators for phytoremediation by phytoextraction, the absorption of certain classes of toxic or at least undesirable chemicals from the soil. Commonly these are ions of heavy metals, such as cadmium (Cd(II)), chromium (both Cr(III) and  Cr(VI)), lead (Pb(II)), arsenic (both As(III) and As(V)), copper (Cu(II)), nickel (Ni(II)), and zinc (Zn(II)). Such processes have been studied in for all those ions, and others such as iron and cobalt. proved to be an active absorber of all those ions, plus some others, and it may well be a hyperaccumulator of both copper and cadmium. It certainly accumulated lead and arsenic very actively and also chromium in the most toxic hexavalent form.

It is not yet clear that would be a useful species for commercial phytoextraction, either for phytoremediation or for phytomining, but there are genetic variables that could, in principle, be selected for. For instance, the ions the plant species absorb are variously bound or chelated by organic acid groups such as oxalate, or by thiol groups, among others. Some, such as arsenate, pass through phosphate metabolic processes before being bound by sulfur groups.

However, a plant that has absorbed some of the levels of toxic substances (e.g., arsenic, lead, or cadmium) that the species can accumulate probably would not be suitable for food or fodder. Thus, phytoextraction sites would have to be protected from livestock.

Prospects for genetic improvement
Such considerations have led some workers to recommend that the plant be actively exploited for its very attractive merits. Frustratingly however, the plant in the wild is very variable; apart from its intrinsic genetic variability, invasive populations have hybridised extensively with other species of that apparently were imported at the same time, and to some extent the genus hybridises in the countries of its origin as well. Apart from such sources of variability, there are considerable variations in ploidy. The unpredictability of the merits of wild strains may frustrate farmers who have tried the species and found that seeds from wild plants do not produce crops that live up to their hopes, so they tend to abandon the attempts.

However, in spite of the associated difficulties, the plants' genetic variability does imply opportunities for genetic improvement. The presence of tetraploids and hexaploids improves the prospects for new variants to be established in the population. The species and its hybrids and variants have attracted attention as valuable prospects for selective breeding for various agricultural purposes. The most desirable and the most undesirable genetically determined attributes have turned out to assort independently, which is a necessary condition for efficient selection of independent characters, so that for example, one can select breeding stock with desirable attributes, without being unable to select for the absence of undesirable attributes. One could select say, lines rich in protein, but without spines.

To appreciate the implications of the variability, consider the following isolated examples of variability in key attributes of dry matter, as found in some 70 samples collected from the south-western United States:


 * crude protein: 5.4–22.3%
 * acid-detergent fiber: 20.1–48.8%
 * acid-detergent lignin: 3.1–10.4%
 * nitrate: 0.1–6.2%
 * water-soluble oxalate: 0.2–9.1%

These figures are not the only important genetically determined variables, but they are illustrative. Note that the high values in the list differ from the corresponding low values by factors ranging from a little over 2 in the case of acid-detergent fibre, to more than 60 for nitrate content. Other physical variables such as size and spininess also diverge markedly. As already noted, in many regions the plant passes through its most palatable and vulnerable phase before the need for forage begins to become more pressing. However, some strains are not spiny, so that there is scope for breeding lines that are useful throughout most of the season. Note too that while some variables, such as protein content, should preferably be as high as possible, others, while harmless or even beneficial at low levels, may be undesirable or even dangerous at the highest recorded levels. For example, rumen flora in ruminants metabolise nitrate and oxalate profitably at modest concentrations, but if the concentration overwhelms their metabolic capacity, the unprocessed ions may poison livestock. Strains of plants selected for modest levels of such content can therefore be fed without strict precautions, but the toxic components of other strains would best be diluted by mixing Kali fodder with other, safer forage, or treating it with mitigating agents. For example, excess soluble oxalate can be precipitated by adding lime to the fodder; precipitated oxalate is harmless. Digestibility also varied in this study, but the digestibility of Kali was in general greater than the digestibility of grasses.

Another desirable trait of Salsola tragus and several related species, is that it is salt-tolerant in arid and sandy environments. In fact, it seems to do best at salt levels that – though modest – are far too high for most crops to tolerate. Growing the plant in environments too saline for most other forage species, even high enough to stress the Salsola, actually increases some of its merits as a forage. In particular, it increases total nitrogen content but reduces some (possibly harmless) levels of potentially toxic substances such as soluble oxalate and nitrate.

Other problems and products


One of the unwelcome attributes of is that it commonly presents a fire hazard, firstly because it is flammable once it is thoroughly dry, partly as a result of its nitrate content, which may be very high, sometimes over 6% dry weight. Secondly, in a season in which the growth has been heavy, high winds often accumulate shocking tangles of the tumbleweeds, covering entire buildings or trapping vehicles so completely as to prevent unaided escape, particularly in the event that the dry material ignites. When they bank up against wire fences, the force of the wind against the mass is likely to damage the fence, and so will the fire if the mass ignites. In wildfire conditions in open country, strong winds often blow burning tumbleweeds across firebreaks, frustrating standard fire control measures. When the burning weeds are stopped by buildings or stacks, they ignite such objects more effectively than any other tumbleweed on the open plains, being compact and woody at maturity, as well as highly flammable.

The complex has been associated with presumably allergic sensitivities to various parts of the plant. Many people develop skin rashes and assorted other reactions after exposure to the plant. Scratches and abrasions from spines or hard stems from the plant may cause itching or inflamed skin. Furthermore, fertilisation in this genus plus most species in the entire family is at least partly by wind pollination, and in some regions their pollen load may represent up to 5% of the total pollen load, causing many allergic sensitizations.

Some species also are harvested for the extraction of compounds such as the alkaloid “salsolin”, used in the preparation of certain pharmaceuticals.

In its dried, tumbleweed form, the plant is generally difficult to work with, being springy, spiny, flammable and brittle, but like many other dried vegetable materials, primarily grass straw, it has been baled and used in building houses in regions such as parts of Nebraska, where not only timber, but even sod, often was in short supply.

Experimental work in Turkey suggests that chopped, milled and briquetted, optionally with the addition of other organic wastes such as sawdust and nut shells, the woody tumbleweed waste makes a usable rural fuel.

In its freshly sprouted form, before it has developed spines or unpleasantly tough fibres, has been recommended as a salad, stir-fry, or potherb for human consumption. Such dishes would be harmless in modest quantities or if the strain used has a low oxalate and nitrate content.