Plants & People: The Intersection of Botany and Human Experience

Wolffia Globosa: The Super Small Superfood

Nomenclatural History

Wolffia globosa (Roxburgh) Hartog & Plas, commonly known as mankai, Asian watermeal, and duckweed, is an aquatic flowering plant. William Roxburgh originally named the specimen Lemna globosa in 1832. However, den Hartog and van der Plas transferred it to the genus Wolffia in 1970. Long before it was assigned a binomial name, mankai was referred to as “Khai nam” by the indigenous people of Thailand (Armstrong, 2021). According to Elias Landholt, the original type specimen seen by Roxburgh could not be found in any of the five herbaria where specimens discovered by Roxburgh are predominantly located (Landholt, 2022). Samples of Wolffia globosa were subsequently collected in West Bengal, where it is believed that Roxburgh collected the original specimen, and studied as a neotype for this reason (Landholt, 2022).

Evolutionary History and Ecology and Life History

The closest known genus ancestors to wolffia are lemna, landolita and spirodela. These are all a part of the araceae family called lemnaceae, which are a family of monocotyledonous flowering plants also known as arums family. Monocotyledons also known as monocots are herbaceous angiosperm plants that are grass/grass like flowering plants which have an embryo with a single cotyledon, they have parallel veins and arrangement of floral organs in multiples of threes. The family lemnaceae are known for being easily distributed by birds in short distances and only live if conditions are suitable and viable for them. Generally these species have expanded due to warming of our climate as well as the eutrophication of the ocean and most waters.

Morphological Description of Vegetative Attributes

Wolffia Globosa has a lineage of many familiar ancestors in which the morphological features are most prominent. Upon visualization of a clade with wolffias closest ancestors, we deduce that size of the vegetative structure is larger in other genus ancestors. Wolffias vegetative structure can range from 0.5 to 1 millimeter in length in large grouped bunches, the next closest ancestors being landolita and lemna which average at 2 mm. The furthest of our focus spirodela then ranges around 5 mm which is 10 times bigger than wolffia. To figuratively represent the actual size to scale of these various structures we can compare it to this image next to a quarter. Another prominent morphological feature of Wolffia that differs with that of its closest genus would be the lack of root on the wolffia, versus that of spirodela, landolita and lemna.

Morphological Description of Reproductive Attributes

While Mankai have undergone a simplification of their vegetative attributes from Spirodela to Wolffia, their reproductive attributes have stayed relatively the same, only changing in size to accommodate the smaller plant. Mankai propagate through vegetative reproduction, which is a type of asexual reproduction. As mankai are autogamous, the parent plant contains both a stigma and a stamen. The parent also contains a basal reproductive pouch where daughter fronds will grow upon fertilization (Armstrong, 2021). Parent plants reproduce exponentially through budding, and, under optimal conditions, are able to double their mass in roughly 48 hours (Yang et al., 2021). As mankai reproduce from November to July, their rapid growth rate and overall hardiness suggest that they could potentially be a sustainable form of plant-based protein that could be used to combat food insecurity (European Food Safety Authority, 2021).

Domestication History

Wolffia has a domestication history that is widely used for a broad spectrum of uses such as production of feed, food, biofuel and biogas (Frontiers in Sustainable Food Systems). This plant being highly domesticated for broad uses is due to its high and fast reproductive rate leading to a high biomass yield. One example of the domestication variables in delineating favorable morphological features was based on differences in chemical composition of flavonoids and isoforms of allozymes. (Frontiers in Sustainable Food Systems). The original use of wolffia stemmed from the use as a farmfeed for livestock and other animals, whereas it was then selectively domesticated for modern day use in vast variable fields as shown above. One more so modern day domesticated use has been the creation of a superfood powder in which many individuals use as a superfood additive for consumption, in which the wolffias pack a high protein content therefore selected for high protein content.

Cultivation Practices

Mankai grows on the surface of calm freshwater bodies of water such as ponds, lakes, and marshes. It is native many countries throughout Asia, including Thailand, Laos, India, China, Indonesia, and Myanmar. It can also be found growing natively in Hawaii and California, where it was discovered by W.P. Armstrong in 1984. Due to its rapid growth rate, Mankai is only harvested, not cultivated, by indigenous peoples living in the aforementioned Asian countries. The yearly harvest takes place twice a week from November to July (European Food Safety Authority, 2021). Nets are typically used to collect the mankai from the surface of the water. The recent commercialization of mankai has led to the utilization of aquatic farms and vertical farming, both of which utilize fertilizer, to cultivate mankai on a larger scale. According to the European Food Safety Authority (EFSA), the composition of mankai grown through vertical farming actually does differ from the composition of mankai in natural ponds. However, the EFSA concluded that these slight differences in nutritional value do not raise safety concerns regarding human consumption of mankai that is cultivated through vertical farming (European Food Safety Authority, 2021).

Nutritional Value 

Mankai has recently become popular in the western world due to its nutritional benefits. The entire plant is consumed. Although it can be eaten raw, it is traditionally cooked before consumption. According to a study on the protein bioavailability of mankai conducted by Kaplan et al. in 2019, Mankai contains all nine essential amino acids, namely histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine, dietary fibers, polyphenols, which help to manage blood pressure levels, iron, zinc, and vitamin B12, which is important for keeping blood and nerve cells healthy (Kaplan et al., 2019). Furthermore, as mankai is more than 45% protein, when measuring by dry weight, it is currently emerging as a new substitute to animal-based protein sources (Kaplan et al., 2019).

Historical Accounts and Human Experience

Traditionally, mankai has been treated by indigenous peoples in the aforementioned Asian countries as another vegetable that is simply incorporated into their diet. In Thailand, for example, mankai is a key ingredient used across many dishes in Isan, a type of Thai cuisine. In addition to its culinary uses, mankai has also traditionally been used as animal feed. Bu Sayemi, who is pictured cultivating mankai on the right, is a 35-year-old farmer from Indonesia. Bu Sayemi harvests nearly five kilograms, or eleven pounds, of mankai a day to feed her two cows and 20 ducks (Bu Sayemi’s Story). Aside from its culinary and agricultural uses, mankai has the potential to be a key tool in battling water pollution. Mankai has the ability to uptake “carbon, nitrogen, phosphorus, pathogens, and toxins,” which allows it to effectively act as a natural water filter (Hill, 2018). These attributes suggest that mankai could potentially be used in developing countries to address problems with poor sanitation. However, as mankai is a very invasive species, the potential ramifications of its implementation would need to first be evaluated.

References 

Appenroth, K. J., Borisjuk, N., & Lam, E. (2013). Telling Duckweed Apart: Genotyping Technologies for the Lemnaceae. Chinese Journal of Appplied Environmental Biology, 19(1), 1–10. https://doi.org/10.3724/sp.j.1145.2013.00001

Armstrong, W. P. (2021, July 4). Wayne Armstrong’s Treatment of the Lemnaceae. Palomar College. Retrieved May 26, 2022, from https://www2.palomar.edu/users/warmstrong/1wayindx.htm

Bog, M., Appenroth, K. J., & Sree, K. S. (2019). Duckweed (Lemnaceae): Its Molecular
Taxonomy. Frontiers in Sustainable Food Systems, 3. https://doi.org/10.3389/fsufs.2019.00117

Bu Sayemi’s Story: Duckweed and Duck Egg Business. (2007, June 6). Biogas Rumah. Retrieved May 29, 2022, from https://www.biru.or.id/en/2017/06/06/5097/bu-sayemis-story-duckweed-and-duck-egg-business.html

Harvesting. Inland Aquatics. Retrieved May 28, 2022, from http://inlandaquatics.ca/?page_id=8

Hill, P. (2018, May 8). Duckweed Control In Wastewater Lagoons. Triplepoint Environmental. Retreived May 27, 2022, from https://lagoons.com/blog/aeration/duckweed-control/

Farabee, M. J. (2007, June 6). Plants and Their Structure II: Monocots and Dicots. Online Biology Book. Retrieved May 22, 2022, from https://www2.estrellamountain.edu/faculty/farabee/biobk/BioBookPLANTANATII.html

Klaus, J. A., Nikolai, B., & Eric, L. (2013). Telling Duckweed Apart: Genotyping Technologies for the Lemnaceae. Chinese Journal of Applied Environmental Biology, 19(1), 1–10. https://doi.org/10.3724/sp.j.1145.2013.00001

Landolt, E., Duckweed Family. Flora of North America. Retrieved May 27, 2022, from http://www.efloras.org/florataxon.aspx?flora_id=1&taxon_id=10488

Landolt E. (1994) Taxonomy and Ecology of the Section Wolffia of the Genus Wolffia (Lemnaceae). Berichte des Geobotanischen Institutes der Eidg. Techn. Hochschule, Stiftung Rübel 60: 137-151. http://doi.org/10.5169/seals-377790

Pagliuso, D. (2018, July 20). Correlation of Apiose Levels and Growth Rates in Duckweeds. Frontiers. Retrieved May 25, 2022, from https://www.frontiersin.org/articles/10.3389/fchem.2018.00291/full

Technical Report on the notification of fresh plants of Wolffia arrhiza and Wolffia globosa as a traditional food from a third country pursuant to Article 14 of Regulation (EU) 2015/2283. (2021). EFSA Supporting Publications, 18(6). https://doi.org/10.2903/sp.efsa.2021.en-6658

Wang, W., Kerstetter, R. A., & Michael, T. P. (2011). Evolution of Genome Size in Duckweeds (Lemnaceae). Journal of Botany, 2011, 1–9. https://doi.org/10.1155/2011/570319

Yang, J., Hu, S., Li, G., Khan, S., Kumar, S., Yao, L., Duan, P., & Hou, H. (2020). Transformation Development in Duckweeds. The Duckweed Genomes, 143–155. https://doi.org/10.1007/978-3-030- 11045-1_15

Yang, J., Zhao, X., Li, G., Hu, S., & Hou, H. (2021). Frond architecture of the rootless duckweed Wolffia globosa. BMC Plant Biology, 21(1). https://doi.org/10.1186/s12870-021-03165-5

This page has paths:

This page has tags:

Contents of this tag:

This page references: