"Cannabis has been cultivated in nearly every province and climatic zone in China from ancient times to the present"

Submitted by Norm Roulet on Wed, 06/16/2010 - 09:30.

December 29, 2009 - China executed a British citizen, Akmal Shaikh, caught smuggling heroin

When United States leaders speak of developing our "homeland security" by drilling and stripmining our way to "energy independence", I must question their scientific integrity and intellectual competency.

It is well understood worldwide that our Federal government has made impossible the development of an industrial hemp economy in America, which offers citizens a greater degree of energy independence here, because past corporate tycoons were able to force corrupt and ignorant politicians to incorrectly associated "hemp" with "marijuana", and "marijuana" has incorrectly been branded as dangerous and addictive by many ignorant and corrupt American scientists, and the corporate tycoons who pay their salaries.

Long story short, because of the ignorant 1936 low-grade American exploitation film called "Reefer Madness", the tuly mad leadership of America has long outlawed developing industrial hemp resources, intellectual property, and technologies in America.

Yet hemp is used worldwide, including in America (with imported hemp... duh), to make over 25,000 products... it is an astounding, profitable crop for fuel, fiber, food and biomass... and it is important to the economy of the world, as regions seek clean, renewable fuelstocks for energy independence. 

Hemp is not in any way a drug, and even cultures with the most strict drug policies... like China, which executes heroin traffickers (above video)... embrace hemp and medicinal cannabis as important, legal natural resources and feedstocks to industries core to national and global public health and thriving world economies.

As the United States government regulates the industrial hemp variety of cannabis as a controlled substance - in a practical sense, now regulated here more strictly than the medicinal "marijuana" variety of cannabis - our nation has little in the way of embedded industrial hemp brainpower, experience, technology, labor and infrastructure upon which to grow hemp economies, causing significant Homeland Security issues.

The U.S. is the only major nation with such a self-imposed industrial hemp economy blight, and many enlightened state and federal government leaders are working to change federal legislation to legalize hemp. Ron Paul has introduced H.R. 1866: Industrial Hemp Farming Act of 2009, and the leadership of progressive agricultural states like North Dakota, Vermont, Michigan and now Ohio are changing state laws to legalize industrial hemp industries for their farmers and citizens, from the home rule level up.

While the U.S. Congress has been studying legalizing industrial hemp for years, Canada has recently legalized cannabis farming and seen many thriving industrial hemp economies develop... including offering Canada profitable new imports to America. From Wikipedia: "hemp and wool from sheep are the main areas of fiber production of Canada" and "cannabis is an important crop in some areas, making up 5% of British Columbia's GDP. According to BC Business Magazine, the crop is worth $7.5 billion to the province annually, and gives employment to 250,000 people. Québec produces an even bigger crop."

What will Ohio leaders do to develop a new economy worth $7.5 billion annually, and creating 250,000 new jobs?!?!

American farmers are seeing Canadian farmers just across the U.S. border growing more profitable and promising crops than are legal in America, and American farmers want to profit from growing cannabis as well... and well should!

But even as we bring to America legalization of industrial hemp at the state and then Federal level, America is a paradigm away from having a thriving hemp economy - Americans don't know how to grow the hemp economy.

There is considerable excellent science dedicated to hemp research and technology elsewhere around the world, which we may learn from now, and I propose for Northeast Ohio to now strategically collect here all the world-class industrial hemp intellectual property, from around the world, to jump-start re-birthing America's industrial hemp economy, from Ohio. My objective is to develop here a global knowledge-center, clearinghouse, intellectual transfer point, and research and development hub for regional leadership in development of industrial and medicinal cannabis industries worldwide.... just as our leaders have hoped to do with "clean coal" and now wind, solar and fuel cells.

I believe the leaders and citizens of America will be amazed by what they learn from development of our cannabis economies.

For example, "Taxonomic studies of Cannabis in China" finds that "Cannabis has spread naturally and has also been cultivated in nearly every province and climatic zone in China from ancient times to the present", but "Cannabis smoking is not popular or widespread in China".

So, where medicinal and industrial cannabis grow freely as a weed, "marijuana" is not "abused" as a "drug". In fact, Chinese government research finds "drug" Cannabis "is erroneously considered addicting".

It is safe to say that if Cannabis "drug abuse" is not a problem in the world's largest country, where "Cannabis has spread naturally and has also been cultivated in nearly every province and climatic zone", then China correctly concludes Cannabis "is erroneously considered addicting"... they have bothered to do the research to escape ignorance. By not becoming a nation of "stoners", the people of the Independent Green Republic of China have proven the leaders of America parochial and ignorant, while setting the standard for global excellence in so many aspects of the world economy, including developing the global industrial hemp economy.

For America's leaders to expect worse of the people of America is disrespectful, ignorant, and selling our citizens short.

Time for America to get down to some real science with cannabis industry research and development, for a brightest greenest state of Earth... to be centered in Northeast Ohio, with considerable help from friends in China and everywhere else already free to be bright and green on Earth.

Taxonomic studies of Cannabis in China

Shao Hong1 and Robert C. Clarke2

1 Department of Biology and Genetics, Beijing Medical University, Beijing 100083, PRC
2 Projects Manager, International Hemp Association, Postbus 75007, 1070 AA Amsterdam, The Netherlands


        Shao Hong and Robert C. Clarke 1996. Taxonomic studies of Cannabis in China. Journal of the International Hemp Association 3(2): 55-60.
        Many aspects of Cannabis taxonomy and systematics have been studied in the People's Republic of China (PRC) since it was founded in 1949.  Most of the reports indicated that only one species (Cannabis sativa L.) exists in China and consists of two infra specific taxa (variously indicated either as subspecies, varieties or forms) sativa and indica.  The fiber

types low in THC are classified as subspecies sativa and drug types with higher THC contents are classified as subspecies indica.  These drug varieties are found south of 42ƒN latitude in western China and south of 30ƒN latitude in eastern China.  Since classical taxonomic studies fall short of fully answering questions about the evolution of Cannabis in China, various molecular methods are suggested.


Introduction
        Cannabis has spread naturally and has also been cultivated in nearly every province and climatic zone in China from ancient times to the present.  The fibers of Cannabis stalks are most commonly used to make ropes, clothes and other textiles, while its seeds are pressed for their oil, or are eaten raw or roasted as snacks between meals (especially in northwestern Yunnan Province).  They are also mixed in buttered tea by Tibetans.   Some Cannabis is illicitly planted for smoking in the Xinjiang Province of northwestern China.  Drug Cannabis is rarely, if ever, applied as a medicine in Chinese hospitals because it is erroneously considered addicting.
        Besides the general name Da Ma (great hemp), the Chinese vernacular terms for Cannabis include Huo Ma (fire hemp), Xian Ma (line hemp) and Huang Ma (yellow hemp).  The fruits of Cannabis are called Ma Zi (hemp seed) and Huo Ma Ren (fire hemp seed).  The female inflorescences are called Ma Fen (fragrant hemp branch).  The terms Da Ma, Xian Ma, and Huang Ma for the plants and their products and Da Ma Zi or simply Ma Zi for the fruits are usually applied to the fiber and seed producing C. sativa cultivars and landraces. Cannabis smoking is not popular or widespread in China.  The terms Da Ma and Huo Ma are only rarely used to denote smoking Cannabis in the south and east of China. However, Huo Ma is much more commonly used by traditional Chinese pharmacists to denote the cleaned hemp seeds incorporated into local herbal stomach remedies.  The seeds for medical use most often come from either cultivated or naturalized C. sativa landraces.
        Chinese scientists have carried out thorough research on the genus Cannabis and their articles, published in diverse Chinese books and journals, cover nearly all aspects of its study from practical agronomy to public health concerns.  This paper concentrates on the literature pertaining directly to the taxonomy and evolution of the genus Cannabis as well as supporting literature from the fields of comparative anatomy and morphology, natural products chemistry, and the most recent tentative approaches to analysis.

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History and literature
      Contemporary Chinese Cannabis studies began in the 1950's, soon after the People's Republic of China was founded. During those days, a general natural resources survey was carried out all over China.  The medicinal and economic values of Cannabis were first recorded in Flora of Chinese Medicinal Plants (Pei and Chou 1951) and it is also recorded in the Chinese Pharmacopoeia of 1957.  Chinese scientists early noticed that Cannabis is a widely distributed plant in China and has medical and other productive applications.  Two of the first Chinese books on plant taxonomy, Pictorial Handbook of Chinese Plants (Chia et al. 1958) and Dictionary of Families and Genera of Chinese Seed Plants (How 1958), simultaneously named Cannabis from China as C. sativa L.  Since this name was also recorded in Iconographia Cormophytorum Sinicorum (ASBI 1972), one of the most comprehensive and highly respected Chinese plant taxonomy reference books, C. sativa L. has been regarded as the representative name for Chinese Cannabis.
        Another form name, C. sativa L. f. ruderalis (Janisch.) Chu, was recorded in Flora Plantarum Herbacearum Chine Boreali-Orientalis (Chu 1959).  This new form name was also adopted by Flora of Chinese Economic Plants (Anon. 1961) and specifically represented the Cannabis distributed in some areas of northeastern China.  The specimens representing this form in Chinese herbaria do not exhibit the key anatomical character described by Janischevsky (1924), i.e., that the fruit base becomes elongated and forms a "caruncle".  However, his collections from Altai and Yili in Xinjiang Province possess the so-called "caruncle" only in some fruits from the same plant.  The lack of a caruncle may result from incomplete maturation.  Based on the lack of consistent expression of this primary discriminating character, both the form name and the original species name are questionable.
        Zhao (1991) proposed that there are four varieties of C. sativa L. distributed in China; sativa, spontanea, indica and kafiristanica.  However, while only presenting a basic classification key derived from Small and Cronquist (1976), she did not provide Chinese representative voucher specimens or delimit the range of these taxa except that the specimens from Fukang, Xinjiang, was identified as spontanea.
        The Morphology Department of the Botanical Institute of the Academia Sinica (ASBI 1960) reported on the pollen surface features of Chinese Cannabis in Pollen Morphologies of Chinese Plants.  The ASBI Handbook of Chinese Oil Plants (1973) discusses the constituents of Cannabis seed oil.  Other important chemical components of Cannabis such as the cannabinoids, and the terpenoids which account for its unique aromas, are listed in Lexicon of Chinese Traditional Medicinal Plants (Jiangsu New Medical College 1975), Compilation of Chinese Herbal Medicines (Anon. 1978) and Flora of Economic Plants in Shandong Province (Anon. 1978).  Other papers scattered in various journals report the cannabinoid content of specimens from several provinces (e.g. Ling et al. 1985, Liu et al. 1992, Chen et al. 1993, Zhan et al. 1994).
        Large scale comprehensive scientific research on Cannabis from 1986 through 1990 (encompassing the disciplines of chemistry, anatomy, morphology, pharmacognosy, drug use survey, etc.) was carried out in several institutes in a coordinated program organized by the National Institute for the Control of Pharmaceutical and Biological Products under the organization of the Bureau of Public Health.  The results are collected mostly in Corpus of Scientific Theses on Cannabis (Anonymous 1991).

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Achievements and problems
      China is one of the largest countries in the world, covering over 9.6 million square kilometers.   There are cultivated landraces, feral escapees from cultivation and truly wild Cannabis populations in China.  Chinese Cannabis populations from different locations vary widely in morphology, chemical contents and levels of biologically active compounds, but much of the same variation can also be found within single plants at varying stages of development.  Climatic and edaphic conditions also cause wide variation in proposed taxonomic characters and often confound attempts at accurate systematic analyses.  Collecting and classifying accessions from various conditions of climate, elevation, microclimate and soil leads to ambiguous results.  Since most Cannabis varieties are dioecious, (the morphologically different male and female flowers are borne on separate plants), morphological taxonomic decisions should be based on observations of both staminate and pistillate individuals.  However, many herbarium specimens are collected from juvenile plants and so are devoid of any flowers.  It is important to collect samples during a common developmental "window" (i.e., floral maturation) so that data can be compared more accurately.  This can only be accomplished by growing accessions in a common garden and carefully sorting herbarium samples by developmental maturity and sexual type.
        Specimens of Chinese Cannabis are mostly kept in the regional herbaria of the Botanical Institute of the Academia Sinica (ASBI) and some larger universities.  Herbarium specimens and fruits are also preserved in some institutes and universities at which the studies on Cannabis were carried out in recent years, such as Beijing Medical University and the National Institute for the Control of Pharmaceutical and Biological Products.  Other Cannabis taxonomic materials are mostly found in the local departments of the Bureau of Public Health.
        Morphological and anatomical studies of herbarium specimens and living samples of Chinese Cannabis reveal the following unique observations.  Cultivated varieties have significantly larger fruits than the wild populations.  Size of the fruits is only a stable criterion of classification as to whether samples are cultivated or wild forms, but does not indicate geographical origin.  Surface patterns of the persistent vestigial perianths adherent on the achenes show some differences between the wild and the cultivated forms.  Wild fruits generally have deeper, and more irregularly dispersed, pigmented areas (blotchy spots and stripes) than those of the cultivated ones.  All other morphological and anatomical parameters found to vary widely due to environmental influences are not suitable as criteria for taxonomic and evolutionary studies.
        The content of delta-9-THC in fruiting inflorescences of Chinese Cannabis, from different individual plants, ranges across a broad scale from 0.02% to 4.38% of dry weight (Zhao 1991, Zhan et al. 1994).  THC content can vary widely even among individual samples taken from the same inflorescence.  In addition, THC breaks down slowly at room temperature.  This means that samples must be fresh, large and well-homogenized to provide accurate results.   Landraces cultivated for drug use are generally the highest in THC, while those cultivated for fiber and seed uses are the lowest in THC.  Escaped populations have THC contents approximating those of the related cultivated populations, and wild populations generally have low THC contents.  According to the forensically-oriented view of Small and Cronquist (1976), all samples grown for producing Cannabis cigarettes (Ma Yan) in Xinjiang Province can be classified as members of the "drug" group (THC greater than 0.3% of dry weight).  Therefore, as an amendment of general opinion, the distribution of Chinese drug type Cannabis might be expanded to include areas south of 42ƒN latitude in the Xinjiang Province of western China, in addition to the regions of southern and eastern China, south of 30ƒN latitude.
        Liu et al. (1992) reported that there is little or no THC, CBD or CBN in the stems and leaves of male plants both from Shache and Kashi, Xinjiang, while there are higher contents of THC in the stems and leaves of female plants from the two areas.  They stated that only the female plants contain medicinal properties or are used for smoking.  The upper inflorescences, younger leaves and resin gland secretions of female plants are used for making Cannabis cigarettes in Kashi, Hetian and Aksu in Xinjiang.  The THC content of Xinjiang Cannabis cigarettes ranged from 0.42% to 1.06% of dry weight in Kashi Prefecture, and the average THC content of Cannabis cigarettes from Shache was 0.79% of dry weight (Chen et al. 1993).
        The comparative histology of the stalk (Zhao 1991) showed that the average number of vessels in vessel groups of xylem in 40 samples of Cannabis (sp. and subsp.) from 24 regions of China is variable.  This finding disagrees with the results of Anderson (1974) who found the average numbers of vessels in vessel groups of xylem in C. sativa and C. indica were 1.39 and 3.05 respectively.  However, it must be remembered that what Anderson called C. indica may have been what Chinese taxonomists usually refer to as C. sativa ssp. indica, and may also have included samples of what the Russian taxonomists Vavilov and Bukinich (1929) called C. indica ssp. afghanica or C. indica ssp. kafiristanica.  Chinese herbarium collections do not include any examples of these taxa.  The existence of only a few calcareous crystals in Chinese Cannabis also differs from Anderson's observations of C. indica.
        Experimental taxonomic studies of Cannabis, including statistics of germination rates of seeds, making artificial hybridizations and analysis of hereditary characteristics of filial generations, were carried out at Beijing Medical University from 1990-93, under the supervision of Prof. Cheng Ching-young, one of the most well-known taxonomists in China.  Her results revealed that few important taxonomic criteria can be used to distinguish the samples from Xinjiang, Gansu, Inner Mongolia and Ningxia Provinces in northwestern China.  From the dissertation of one of her students (Yang 1993), Cheng concluded that there is only one species (C. sativa L.) consisting of two forms: (f. sativa and f. indica) in China.   It is possible to distinguish this (as well as more subtle) genetic differences between cultivated and wild forms by means of further DNA analyses.
        Since there are no classical taxonomic characters suitable to classify species and varieties of Cannabis, other new appropriate technologies have been introduced into this field.  A project using advanced molecular methods was started at Beijing Medical University in late 1993 (Shao and Liu 1994).  The chromosome number of Cannabis is 2n=20 (Harlan et al. 1973), but there is little information concerning chromosome karyotype, genome or DNA.   Employing the molecular genetic techniques of DNA polymorphisms, the molecular genetic variations of Chinese Cannabis resources can be better investigated and the evolutionary relationships between wild populations, landraces, and cultivars can be revealed.
        Data reflecting the relatedness of differing populations is also valuable to modern plant breeders wishing to utilize diverse gene pools in the development of modern Cannabis cultivars.  The goals of current work are to: 1) determine the distribution of wild, semi-wild and cultivated Cannabis in China, 2) compare accessions at the molecular genetic level, 3) determine origins of cultivated Cannabis taxa and evolutionary relationships between them, as well as between wild and cultivated taxa, 4) make molecular identification of sex during early developmental stages of Cannabis, 5) determine the molecular genetic differences between fiber and drug types of Cannabis and 6) determine the range of genetic variation in modern landraces and cultivars.
        Presently, we have some preliminary experimental results: 1) The DNA lengths of Cannabis from Yunnan, Guizhou and Xinjiang Provinces are about 10-20 kilobases. 2) Cultivated samples have mutations in the DNA structure indicative of artificial selection. 3) DNA restriction fragments are different between the cultivated samples and the wild samples. 4) The samples of different sexes exhibit unique identifiable fragments. 5) Identifiable genetic fingerprints exist in different accessions.  Recent discoveries about Cannabis DNA encouraged us to continue the project, but further achievements must be supported by additional funding.

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Prospective endeavors
      Considering the difficulties of Cannabis research, the hidden relationships between Cannabis varieties or populations require that new and more advanced techniques be introduced and combined with conventional studies of Cannabis.  Following the progress in other disciplines (e.g., blood/tissue typing and genome mapping), studies of classification, systematics and evolution in Cannabis might successfully use modern molecular techniques to solve problems for which conventional methods are inadequate.
        Currently, there are several techniques of DNA polymorphism analysis successfully used to find genetic correlations, to detect evolutionary relationships, and to identify a hybrid's possible parents.  They have been concerned with plant taxa ranging from families to varieties, in more than 10 families and 20 genera.  These modern molecular techniques include: VNTR (Variable Number of Tandem Repeats), RFLP (Restriction Fragment Length Polymorphisms), AP-PCR (Arbitrarily Primed Polymerase Chain Reaction), DAF (DNA Amplification Fingerprint), RAPD (Random Amplified Polymorphic DNA), etc.  Other methods applicable to investigation of polymorphisms in mitochondrial and chloroplast DNA have also been developed.   These readily available "DNA fingerprint" methods can be used to analyze plant genomes.  Two or more of these DNA data, when compared to each other and to other taxonomic data, could greatly improve our understanding of the systematics and evolution of Cannabis.
        The Chinese National Natural Science Foundation has supported some molecular taxonomic and systematic projects that mostly employed the technology of chloroplast DNA restriction maps to study wild species in Vitis, the Convallariaceae and Gnetaceae, ferns etc., since 1989 (Qi and Gao 1990 and 1991, Zhu 1992, Zhu and Qi 1993).  A few papers about molecular taxonomy and systematics can be found in Chinese scientific journals (Shi 1993, Hong 1993, Shao and Liu 1994, Huang et al.).  Most are reviews and conclude that modern molecular technologies can be used to solve plant taxonomic, systematic and evolutionary problems.  DNA fingerprint studies of Chinese Cannabis in Beijing Medical University enlisted the modest support of the Bureau of Public Health at the end of 1993, but the project is now short of funds.
        We are confident that when the continuing vigorous development of modern molecular biological techniques is accompanied by improvement of our financial environment, research on Cannabis in China will progress greatly and will contribute additional valuable evidence to the studies and applications of Cannabis worldwide.

References

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        Interested researchers may request the list of Chinese Cannabis herbarium accessions used to make the distribution map on page 57.

 

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