Fallopia, Adans.

Drazan, Dallas, Smith, Alan G., Anderson, Neil O., Becker, Roger & Clark, Matthew, 2021, History of knotweed (FOllopiO spp.) invasiveness, Weed Science (Cambridge, England) 69 (6), pp. 617-623 : 618-621

publication ID

https://doi.org/ 10.1017/wsc.2021.62

DOI

https://doi.org/10.5281/zenodo.12659226

persistent identifier

https://treatment.plazi.org/id/0399F47A-0308-2C4B-5536-B534FA40E2ED

treatment provided by

Felipe

scientific name

Fallopia
status

 

Classification View in CoL

The taxonomic classification of knotweed has changed numerous times since its initial classification. Fallopia japonica was originally classified as Reynoutria japonica by Houttuyn in 1777 ( Bailey and Conolly 2000; Beerling et al. 1994; Table 1 View Table 1 ). In 1848 it was reclassified as Polygonum sieboldii Reinw. (= Polygonum cuspidatum Sieb. & Zucc. ) in reference to Phillipe von Siebold, who originally brought specimens to the Netherlands from his sojourn in Japan ( Bailey and Conolly 2000). These two names were combined by Makino in 1901 to create the new nomenclature Polygonum reynoutria Makino ( Bailey and Conolly 2000). The knotweed complex was first classified in the genus Fallopia by Decraene and Akeroyd in 1988 ( Bailey and Stace 1992; Decraene and Akeroyd 1988). Throughout the literature, authors use the Polygonum , Reynoutria , and Fallopia genera. Confusion with the nomenclature of knotweed continues due to the use of multiple specific epithets. Different countries also have different preferences on the nomenclature they use ( Bailey and Wisskirchen 2006).

Distribution and Spread

Fallopia japonica was commercially available in Europe in 1848 ( Bailey and Conolly 2000). In England, the first record of F. japonica dates to the late 1840s ( Bailey 1994). The initial introduction of F. japonica to England was a single male-sterile clone that successfully spread and created a massive knotweed infestation that exists across the United Kingdom today ( Bailey et al. 2008; Hollingsworth and Bailey 2000). The earliest herbarium record of F. japonica in the United States is from 1873 (Barney 2006). Knotweed ( F. japonica ) was being sold in Minnesota as early as 1908 ( Figure 1 View Figure 1 ) (The Jewell Nursery Co. 1908), but residents could have purchased knotweed earlier from nurseries on the East Coast of the United States (Maule’ s Seed Catalogue 1895; James Vick’ s Sons 1898).

Fallopia sachalinensis arrived in Europe in 1864 at the botanic gardens of St. Petersburg, Russia ( Bailey and Wisskirchen 2006). Fallopia × bohemica was not recorded in Europe until the 1980s, when it was first described by Chrtek and Chrtková, although it is now known to have occurred earlier, as early as 1872, and spread undetected ( Bailey and Wisskirchen 2006). The undetected spread is primarily due to the difficulty in visually identifying the hybrid ( Bailey and Wisskirchen 2006). Morphological traits of F. × bohemica are variable and can exhibit traits of F. japonica or F. sachalinensis . Fallopia × bohemica was confirmed in the United States in 2001 ( Bailey and Wisskirchen 2006). Interestingly, F. × bohemica was not described in its native range in Japan until 1997 because the parental species were not sympatric in Japan until that time ( Bailey 2003).

A total of 47% of 92 knotweed populations sampled in the first transcontinental genetic study of knotweed in the United States were identical to the British male-sterile clone of F. japonica ( Grimsby and Kesseli 2009) ; this included one population sampled from Duluth, MN ( Grimsby and Kesseli 2009; see supplemental information here: http://www.genetics.umb.edu). As many as 54% of samples in this study were found to be F. japonica (50 samples), 3% F. sachalinensis (3 samples), and 42% F. × bohemica (39 samples). This contrasts with a study of knotweed in the western United States that found F. × bohemica to be more common than F. japonica with a ratio of 5:1 ( Gaskin et al. 2014). The difference between these two studies could potentially be attributed to the fact that the Grimsby and Kesseli study specifically requested collaborators to collect “Japanese knotweed,” which may have dissuaded collectors from sending in samples of other taxa. There is potential that the composition of knotweed taxa in Minnesota is similar to that seen in other areas across the United States, but without a thorough sampling and genetic testing, it is impossible to know which species is most prevalent.

Invasiveness

It is necessary to first understand what unique characteristics make knotweed such a strong invader in order to ultimately control it. Invasive nonnative plant species have many effects on environments in their adventive ranges. Invasive alien plants reduce the overall fitness and growth of local plant species, decrease plant species abundance and diversity, and decrease animal species’ fitness and abundance ( Vilà et al. 2011). Knotweeds have been shown to reduce the overall biomass of macroinvertebrates in their stands by up to 60% and also negatively impact the biomass, cover, and species richness of native plants ( Lavoie 2017). It has been found that 1.6 to 10 times as many species grow outside knotweed stands as compared to within ( Aguilera et al. 2010). Knotweeds also negatively impact riparian areas by changing leaf litter nitrogen composition ( Urgenson 2006) and reducing ecosystem services such as access to riverbanks ( Kidd 2000). Knotweeds are also often considered aesthetically displeasing ( Kidd 2000).

Managing and eradicating invasive plants can also be extremely costly. An estimated US $500 million is spent yearly on the management of nonnative plant species just on residential properties alone in the United States ( Pimentel et al. 2005). It would cost an estimated €32.3 million ( US $38 million) annually to control all the knotweed populations in Germany ( Reinhardt et al. 2003).

Reproduction

Knotweed can spread asexually by both rhizomes and adventitious rooting of stem fragments ( Bailey et al. 2008). Knotweed primarily spreads via rhizome dispersal occurring from floods or human activity in the adventive range ( Bailey et al. 2008). Reproduction via adventitious rooting of stem fragments results in lower levels of regeneration for F. japonica and F. × bohemica as compared with regeneration from rhizomes. However, F. sachalinensis has higher levels of regeneration from adventitious rooting of stem fragments and only low levels of regeneration when grown from rhizomes ( Bímová et al. 2003). Overall, vegetative regeneration is highest in F. × bohemica ( Bímová et al. 2003) . Knotweeds form shoot clumps or crowns composed of dead shoots from previous growth years and underground wintering buds that give rise to new aerial shoots in the spring ( Bailey et al. 2008; Dauer and Jongejans 2013). Size of crowns varies between species, with F. japonica having larger crowns than F. sachalinensis , while the hybrid, F. × bohemica , has an intermediate crown size ( Bailey et al. 2008).

Fallopia japonica frequently reproduces via seed in its native range ( Bailey 2003; Bram and Mcnair 2004) and has been reported to reproduce via seed in the adventive range ( Bram and Mcnair 2004; Forman and Kesseli 2003), although this is thought to be less common than asexual reproduction ( Bailey et al. 2008). Knotweed produces prolific seed, with a study of F. japonica and F. sachalinensis in Pennsylvania reporting 50,000 to 150,000 seeds annually per stem ( Niewinski 1998). Knotweeds have high germination rates of up to 92% (field germinations) ( Bram and Mcnair 2004), 93% (dried seed) ( Groeneveld et al. 2014), and even up to 100% (overwintered seed) ( Forman and Kesseli 2003). Germination has been shown to rely on seed maturity levels ( Bram and Mcnair 2004). Knotweeds are dioecious, but there are known cases of gynodioecious plants in each taxa ( Bailey et al. 2008; Beerling et al. 1994; Holm et al. 2018; Karaer et al. 2020; Niewinski 1998). There are also reports of androdioecious knotweed from the Amami Islands of Japan (Mitsuru Hotta, personal communication, in Bailey 2003). There is currently no research on knotweed pollen viability reported in the literature. Sexual reproduction may not be an important management concern if there is no pollen donor present. On the other hand, if many viable pollen donors are present, then sexual reproduction is a major concern and a priority for management decisions. That is why it is critical that research be conducted on male and female fertility of knotweed.

Structure of Growth

A study in the Czech Republic found that, on average, invasive species as a whole were 1.2 m taller than native species across all habitat types ( Divíšek et al. 2018). Knotweeds are incredibly tall and range in height from 2 to 4 m thus shading out other plants ( Bailey et al. 2008; Bímová et al. 2001). Fallopia japonica has a smaller overall stature ranging from 2 to 3 m in height; F. sachalinensis is the tallest of the species and reaches 4 m in height; while the hybrid F. × bohemica has the greatest range in height of 2.5 to 4 m ( Bailey et al. 2008). Knotweeds create a monoculture ( Figure 2 View Figure 2 ) with large leaves that form an extremely dense canopy, shading other plants throughout the majority of the growing season, making it difficult for smaller plants to grow in the same area ( Bailey et al. 2008; Siemens and Blossey 2007). This is especially true of F. sachalinensis , whose leaves can reach 40 cm in length ( Bailey and Stace 1992). However, it is worth noting that Moravcová et al. (2011) concluded that shading is unlikely the primary invasive mechanism of knotweeds, as light treatment studies yielded inconclusive results.

It is generally accepted that knotweed rhizomes can grow up to 7 m from the crown of origin, but recent research has shown that F. japonica rhizomes typically extend no more than 4 m ( Fennell et al. 2018). Still, knotweed rhizomes are a formidable opponent, as they can grow up through asphalt ( Wade et al. 1996). They can also cause bank destabilization when growing alongside water bodies, as the rhizomes are less able to bind soil together compared with some native riparian plants ( Reinhardt et al. 2003).

Soil Conditions

Knotweed is an early successional species growing on volcanic ash and recent lava flows in its native habitat in Japan ( Bailey et al. 2008; Barney et al. 2006). The range of habitats and soil types it is known to grow in is extremely diverse. It can be found across 35 latitudinal degrees and grows from sea level to 3,500 m above sea level ( Bailey 2003). It often grows in riparian and ruderal areas, areas experiencing human disturbances, forest margins, urban landscapes, and gardens ( Bailey et al. 2008; Clements et al. 2016; Mandák et al. 2004). It grows on a variety of terrains, including sandy soils, swamps, rocky banks, and alluvial floodplains ( Barney et al. 2006). Knotweeds have highly plastic salt-tolerance traits and are now known to grow in salt marsh habitats in the eastern United States ( Richards et al. 2008). Furthermore, knotweeds are known to grow in soils with high concentrations of metal pollutants ( Michalet et al. 2017). Indeed, knotweed growth rates are greater in soils with average concentrations of metallic pollutants (2 mg kg − 1 Cd, 150 mg kg − 1 Cr, 100 mg kg − 1 Pb, and 300 mg kg − 1 Zn) compared with unpolluted soil ( Michalet et al. 2017). Fallopia × bohemica accumulated the greatest concentration of metals relative to either F. japonica or F. sachalinensis ( Michalet et al. 2017) .

Allelopathy

Fallopia japonica contains chemicals with the potential to cause allelopathic effects; these chemicals include resveratrol, resveratroloside, piceid, piceatannol glucoside, polydatin, emodin, and catechins ( Serniak 2016; Vastano et al. 2000). Fallopia × bohemica has also been found to have allelopathic effects on nearby plants, particularly affecting seed germination and seedling growth ( Siemens and Blossey 2007). One study found that mechanical control of F. × bohemica via stem cutting causes an overall reduction in production of allelochemicals ( Murrell et al. 2011). Fallopia sachalinensis also has allelopathic capabilities and has been shown to have the greatest phytotoxic effects on other plants ( Moravcová et al. 2011).

The highest level of phenolic compounds is found in the rhizomes ( Vaher and Koel 2003). However, the decomposition of knotweed litter from each of the taxa also has phytotoxic effects on other plants ( Moravcová et al. 2011). These allelopathic chemicals are significant, because they greatly increase knotweed’ s invasive and competitive ability.

Genetic Diversity

Knotweed has higher levels of genetic diversity in its native range than its invasive range ( Bailey 2003). There are also many more subspecies and varieties of knotweed in the native range compared with the adventive range ( Bailey 2003; Inamura et al. 2000). Hybridization of knotweed in Japan is limited, which differs from the knotweed found in Europe and North America, where hybridization is common ( Bailey 2003; Grimsby et al. 2007). Clonal invasive species that reproduce asexually typically have lower genetic variation ( Bailey 2003), so it would follow that invasive knotweed would have low genetic variability; however, the ability of an invasive to hybridize can increase its invasive success ( Ellstrand and Schierenbeck 2006). Indeed, F. × bohemica shows heterosis in that it is more invasive than its parents ( Parepa et al. 2014), spreads faster than both parents ( Mandák et al. 2004), and has a higher regenerative ability than its parents ( Bímová et al. 2003).

Knotweed in the United Kingdom shows interspecific diversity, with F. japonica , F. × bohemica , and F. sachalinensis all clustering separately in diversity analyses and F. × bohemica clustering twothirds closer to F. japonica than F. sachalinensis ( Hollingsworth et al. 1998) . This could potentially be due to multiple backcrossing events. It was found that F. japonica and F. × bohemica are most genetically similar, whereas F. japonica and F. sachalinensis are the least similar ( Holm et al. 2018). It has also been found that F. × bohemica shows higher diversity compared with either parent, which could be explained by spread via sexual reproduction ( Hollingsworth et al. 1998).

Low genetic diversity was found for all three of the knotweed taxa across Norway ( Holm et al. 2018). Due to these low levels of genetic variation, it was concluded that knotweed likely has not reproduced sexually in Norway ( Holm et al. 2018).

Within-species genetic diversity was found to be low across all taxa in a study of knotweeds in Poland and Japan ( Bzdega et al. 2016), with F. japonica and F. sachalinensis showing the lowest levels of polymorphism. Fallopia japonica populations in this study were not found to be a single clone.

Fallopia japonica spreads exclusively by vegetative reproduction, and the clones are monotypic in the western United States ( Gaskin et al. 2014). The Gaskin et al. (2014) study used amplified fragment length polymorphisms (AFLPs) to compare F. japonica with multiple samples of the clone that invaded the United Kingdom and found them to be genetically identical. Fallopia sachalinensis was also found to spread primarily by vegetative means and was mostly monotypic in the western United States ( Gaskin et al. 2014). However, F. × bohemica differed from its parents, in that it was found to spread by both asexual and sexual mechanisms, had the lowest number of monotypic populations, the highest proportion of loci that are polymorphic, and the highest genetic diversity ( Gaskin et al. 2014).

A study in Massachusetts that used simple sequence repeat (SSR) markers also found the UK clone of F. japonica in all three of the populations surveyed ( Grimsby et al. 2007). This study found 26 genotypes from 66 samples across three distinct F. japonica populations. They also found evidence for sexual spread of knotweed in Massachusetts, as most knotweed patches were composed of unique genets that were not found in other patches.

A transcontinental study of knotweed analyzed 92 locations across the United States and, using SSR markers, identified 36 genotypes ( Grimsby and Kesseli 2009). Fallopia × bohemica had the most diversity, as it was composed of 26 genotypes, while F. japonica samples were made up of 8 genotypes, and F. sachalinensis had only 2 genotypes. The UK clone of F. japonica was also detected in this study.

Another study used random amplified polymorphic DNA analysis to study the genetic diversity of F. japonica along two creeks in Kentucky ( Wymer et al. 2007). The authors found no evidence of asexual spread and concluded that the genetic diversity that did exist resulted from multiple introductions.

Populations of F. japonica and F. × bohemica have been shown to have a large amount of epigenetic diversity. Epigenetic diversity occurs through processes such as DNA methylation or histone modification instead of DNA base pair changes. One study used AFLP genetic diversity markers to measure genetic diversity, which were then compared with epigenetic diversity levels found using methylation-sensitive AFLP epigenetic diversity markers that could identify methylated cytosine ( Richards et al. 2012). The authors found that a single clone of F. japonica contained 129 epigenotypes, even though it was only composed of one genotype and had no genetic variation ( Richards et al. 2012). This study also analyzed F. × bohemica and found 85 epigenotypes, but only 7 genotypes, across 155 individuals. Both F. japonica and F. × bohemica showed higher levels of epigenetic variation than genetic variation, with the epigenetic variation for F. × bohemica being 10 times higher than its genetic variation. This is important, because epigenetic variation is one explanation for the phenotypic diversity and successful establishment of clonally spread F. japonica in diverse environments with invasive populations that have low genetic variation. ( Banerjee et al. 2019).

In a study of central European F. japonica , a single genotype of F. japonica contained 27 different epigenotypes ( Zhang et al. 2016). The authors also found that the epigenetic variation was a full order of magnitude higher than the genetic variation. Their study was able to correlate epigenetic diversity with both phenotypic diversity and the climate from which the F. japonica population originated. Notably, F. japonica varied in some key phenotypic traits associated with invasiveness, such as specific leaf area. They concluded this correlation could potentially lead to habitat adaptation, which could explain how a single clone of F. japonica was able to become such a strong invader across much of Europe.

It is important that a genetic diversity study be conducted in Minnesota, because it has been shown that each congener can react differently to different control methods ( Bímová et al. 2001). It has also been shown that F. japonica , F. sachalinensis , and F. × bohemica all react differently to biological control with the psyllid Aphalara itadori Shinji ( Grevstad et al. 2013). Thus, it is imperative that land managers and homeowners know exactly which taxa is invading an area so that they can choose the most effective control method.

Ploidy and Cytogenetics

Knotweed has a base chromosome number of x = 11 ( Bailey and Stace 1992). In Japan, high-altitude dwarf F. japonica has been found as a tetraploid (2 n = 4 x = 44), and tall lowland F. japonica has been found as tetraploid and octoploid (2 n = 8 x = 88; Bailey 2003). Limited sampling found F. japonica from China to be octoploid and decaploid ( Bailey 2003). Fallopia sachalinensis is tetraploid in its native range ( Bailey 2003) with the exception of Korean F. sachalinensis being dodecaploid ( Kim and Park 2000).

In the adventive range, F. japonica var. japonica has been found to be octaploid, and F. japonica ‘Compacta’ has been found as a tetraploid ( Mandák et al. 2003). There have been no reports of F. japonica as a diploid. Fallopia sachalinensis has been found as a mixture of tetraploid, hexaploid, and octoploid, and F. × bohemica is primarily hexaploid with evidence for tetraploids and octoploids as well ( Mandák et al. 2003). The hybrid created between F. sachalinensis and Compacta has also been found as a tetraploid ( Bailey and Stace 1992). Even though F. × bohemica can be crossed with itself or either parent, resulting in a range of euploid and aneuploid progeny, it is primarily found in nature in a euploid state as a tetraploid, hexaploid, octoploid, or infrequently a decaploid ( Bailey and Wisskirchen 2006).

Tetraploid knotweed shows normal bivalent pairing in meiosis and a low level of chiasma ( Bailey and Stace 1992). Tetraploid and octoploid F. × bohemica have a more normal meiosis than the hexaploid F. × bohemica ( Bailey and Stace 1992) . The hexaploid F. × bohemica shows irregular meiosis that consists of numerous univalents and multivalents not surpassing quadrivalents ( Bailey and Stace 1992). The DNA 2C-values per 2x genome of the taxa ranged from 1.23 to 1.62 pg, with F. sachalinensis at 1.33 pg, Compacta at 1.29 pg, F. japonica ranging from 1.30 to 1.62 pg, and F. × bohemica ranging from 1.23 to 1.59 pg ( Bailey and Stace 1992). This paper also posits that the tetraploids are much older than the octoploids, because the tetra-haploid genome of F. japonica var. japonica can form bivalents , yet the di-haploid genome of F. sachalinensis cannot.

Ploidy levels of knotweed are important, because they can impart reproductive barriers or reduce fertility, which determine the taxa that can successfully reproduce sexually together. For example, F. japonica can produce seed after pollination by the related species Bukhara fleeceflower ( Fallopia baldschuanica Regel ; syn.: Polygonum baldschuanicum Regel ), but this hybrid seed is infertile and rarely becomes established ( Bailey et al. 2008).

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