J. Range Manage. 54: 447–461 July 2001 Alkaloids as anti-quality factors in plants on western U.S. rangelands JAMES A. PFISTER, KIP E. PANTER, DALE R. GARDNER, BRYAN L. STEGELMEIER, MICHAEL H. RALPHS, RUSSELL J. MOLYNEUX, AND STEPHEN T. LEE Pfister and Ralphs are rangeland scientists, Panter is a reproductive toxicologist, Gardner and Lee are research chemists, and Stegelmeier is a veterinary pathologist with the USDA-ARS Poisonous Plant Research Laboratory, 1150 E. 1400 N., Logan, Ut. 84341. Molyneux, a research chemist, is with the USDA- ARS Western Regional Research Center, Albany, Calif. 94710. Abstract Resumen Alkaloids constitute the largest class of plant secondary com- Los alcaloides constituyen la clase mas grande de compuestos pounds, occurring in 20 to 30% of perennial herbaceous species secundarios de las plantas y ocurren en un 20 a 30% de las in North America. Alkaloid-containing plants are of interest, first especies herbáceas perennes de Norte América. Las plantas que because alkaloids often have pronounced physiological reactions contienen alcaloides son de interés, primero porque cuando el when ingested by livestock, and second because alkaloids have ganado consume alcaloides a menudo producen pronunciadas distinctive taste characteristics. Thus, alkaloids may kill, injure, reacciones fisiológicas y segundo porque tienen caracteristicas or reduce productivity of livestock, and have the potential to distintivas de sabor. Así, los alcaloides pueden matar, dañar o directly or indirectly alter diet selection. We review 7 major cate- reducir la productividad del ganado y tienen el potencial para gories of toxic alkaloids, including pyrrolizidine (e.g., Senecio), alterar directa o indirectamente la selección de la dieta. quinolizidine (e.g., Lupinus), indolizidine (e.g., Astragalus), diter- Revisamos 7 categorías principales de alcaloides tóxicos, penoid (e.g., Delphinium), piperidine (e.g., Conium), pyridine (e.g., incluyendo pirrolizidinae (por ejemplo, Senecio), quinolizidina Nicotiana), and steroidal (Veratrum-type) alkaloids. Clinically, (por ejemplo, Lupinus), indolizidina (por ejemplo, Astragalus), effects on animal production vary from minimal feed refusal to diterpenoide (por ejemplo, Delphinium), piperidina (por ejemp- abortion, birth defects, wasting diseases, agalactia, and death. lo, Conium), pyridina (por ejemplo, Nicotiana), and esteroidal There are marked species differences in reactions to alkaloids. (tipo Veratrum). Clínicamente, los efectos de los alcaloides sobre This has been attributed to rumen metabolism, alkaloid absorp- la producción animal varían desde el rechazo mínimo del ali- tion, metabolism, excretion or directly related to their affinity to mento al aborto, defectos de nacimiento, enfermedades mer- target tissues such as binding at receptor sites. In spite of alka- mantes, agalacia y la muerte. Hay marcadas diferencias entre loids reputed bitter taste to livestock, some alkaloid-containing especies en cuanto a las reacciones a los alcaloides. Esto has sido plant genera (e.g., Delphinium, Veratrum, Astragalus, Oxytropis, atribuido al metabolismo del rumen, la absorción del alcaloide, and Lupinus) are often readily ingested by livestock. Management el metabolismo, la excreción o directamente relacionado a su schemes to prevent losses are usually based on recognizing the afinidad con los tejidos blanco, tal como fijarse en sitios recep- particular toxic plant, knowing the mechanism of toxicity, and tores. A pesar de que los alcaloides tiene reputación de ser de understanding the temporal dynamics of plant alkaloid concen- sabor amargo para el ganado, algunos géneros de plantas que tration and consumption by livestock. Once these aforementioned contienen alcaloides (por ejemplo, Delphinium, Veratrum, aspects are understood, losses may be reduced by maintaining Astragalus, Oxytropis y Lupinus) a menudo son ingeridas por el optimal forage conditions, adjusting grazing pressure and timing ganado. Los esquemas de manejo para prevenir perdidas usual- of grazing, aversive conditioning, strategic supplementation, mente son basados en reconocer una planta tóxica en particular, changing livestock species, and herbicidal control. conociendo el mecanismo de toxicidad y entendiendo las dinámi- cas temporales de la concentración de alcaloides en la planta y su consumo por el ganado. Una vez los aspectos antes mencionados Key Words: poisonous plants, plant toxins, forage quality, diet son entendidos, las perdidas se pueden reducir manteniendo selection, grazing management condiciones forrajeras óptimas, ajustando la presión y tiempo de apacentamiento, induciendo un condicionamiento aversivo, uti- Alkaloids are a chemically-diverse group of plant compounds lizando suplementación estratégica, cambiando las especies de with widely varying biological activities when consumed. ganado y controlando las especies toxicas con herbicidas Although most effects are thought to be detrimental, many alka- loids have been developed into beneficial drugs and pharmaceuti- cals. Range plants that contain alkaloids, poison more livestock worldwide than any other class of toxic compounds. The eco- nomic loss to the livestock industry specifically from alkaloid- Invited paper presented at the symposium “Anti-Quality Factors in Rangeland containing plants is not known, but livestock losses in cattle and and Pastureland,” Feb. 23-24, 1999, Omaha, Nebraska. Pfister’s email: sheep in the western states to all toxic plants are estimated to [email protected]. exceed $340 million (Nielsen et al. 1988), not including horses Manuscript accepted 27 Nov. 00. JOURNAL OF RANGE MANAGEMENT54(4), July 2001 447 Table 1. Direct and indirect economic losses from poisonous plants related to production and off Do Alkaloids Alter Diet take from domestic livestock and wildlife. Alkaloid-containing plants are responsible for the Selection? majority of livestock losses to poisonous plants worldwide. Direct losses Indirect losses Alkaloids are reported to taste bitter Death Added fencing to restrict access (Bate-Smith 1972). Garcia and Hankins Wasting/reduced weight gains Herding costs (1975) argued that animals acquire natural Neurological incapacitation (horses) Supplemental feeding aversions to most alkaloids because bitter Abortions Changes in grazing management taste is often linked with toxicity. Some Weak/small offspring Increased veterinary costs for treatment forage plants such as reed canarygrass Reduced fertility Lack of immune response to vaccines (Phalaris arundinaceae L.) and certain Birth defects Lost opportunity to graze forage Inability to sell/harvest animals Lost nutrients in ungrazed forages lupines (Lupinus spp.) are unpalatable Reduced land values because of high alkaloid concentrations Reduced value of grazing permits (Ralphs and Olsen 1987). Nonetheless, Herbicide costs for suppression Robinson (1979) and Glendinning (1994) Increased risk in overall enterprise concluded that alkaloids are not universally repellent to herbivores. Additionally, and goats. This estimate includes only because specific structural features are Molyneux and Ralphs (1992) suggest that death and reproductive losses (e.g., abor- responsible for the biological activity of some toxic alkaloids are not bitter tasting to tions), but other indirect costs also impact the individual compounds. Some alkaloids livestock. Sheep (Arnold and Hill 1972), the livestock industry (Table 1). Our possess a close structural similarity with cattle (Pfister et al. 1996a, Panter et al. objective is to scrutinize the effects of neurotransmitters such as acetylcholine 1997), and pigs (Panter et al. 1985) do not alkaloid-containing plants on livestock (Ach), dopamine and serotonin. This necessarily avoid bitter tastes, nor do sheep production on western rangelands and out- structural similarity partially explains the form stronger aversions to bitter than to line management solutions. We sequen- toxicity of some alkaloids in the central sweet flavors (Launchbaugh et al. 1993). tially review 7 major categories of toxic nervous system (CNS). As a rule, grazing animals are not deterred alkaloids, including pyrrolizidine, quino- Alkaloids occur in about 20% of all vas- by the supposed bitterness of alkaloid-con- lizidine, indolizidine, diterpenoid, piperi- cular plants, with most found in dicotyle- taining plants. Intake of alkaloid-containing dine, pyridine, and steroidal alkaloids. dons (Hegnauer 1963, 1988, Hazlett and plants is primarily regulated by positive or Sawyer 1998). More than 33% of annual negative postingestive consequences (see herbs in North America contain alkaloids Launchbaugh et al. this volume). Alkaloids—Definition and (Levin 1976). Fortunately for livestock Distribution producers, the only monocotyledon family Indolizidine alkaloids with significant (> 0.05% of dry weight) alkaloid concentration is Liliaceae Alkaloids are difficult to define because (Robinson 1979). Obviously, this state- Major Plant Species of their diversity, but the alkaloid chemist ment ignores alkaloids in monocots pro- The indolizidine alkaloid, swainsonine, S.W. Pelletier (1983) defined alkaloids as duced by fungal endophytes (see is the toxin in locoweeds (Molyneux and “a cyclic organic compound containing Thompson et al. this volume). The major James 1982), found within the Astragalus nitrogen...” The presence of a nitrogen alkaloid-containing plants on western and Oxytropis genera of the Fabaceae. atom usually makes alkaloids basic, as ranges are classified by the type of alka- There are more than 350 species of suggested by their name. Alkaloids are loid they contain (Table 2). Astragalus and about 30 species of classified by their heterocylic ring struc- Oxytropis in North America. Of these ture and the location of the nitrogen atom species, only about 10 Astragalus and 2 in the ring. Ring structure is important Table 2. Major classes of plant alkaloids, livestock species primarily affected, body system(s) affected, and major plant genera containing the alkaloids. Type of Alkaloid Animal Species Body System(s) Affected Plants Containing Toxin Primarily Affected Common name Scientific name Diterpene Cattle Muscle paralysis larkspur Delphiniumspecies Pyrrolizidine Cattle, horses Liver toxin; photosensitization groundsel Seneciospecies houndstongue Cynoglossum officinale Steroidal (solanum type) Cattle, sheep, horses CNS1toxin; digestive tract nightshades Solanumspecies Steroidal (veratrum type) Sheep Birth defects; lung congestion skunk cabbage Veratrum species death camas Zigadenusspecies Piperidine Cattle, sheep, horses, pigs CNS toxin; birth defects poison hemlock Conium maculatum lupine Lupinusspecies tobacco Nicotianaspecies Quinolizidine Cattle, sheep, horses Respiratory paralysis;birth defects lupine Lupinus species Indolizidine Horses, cattle, sheep Digestive, reproductive & CNS locoweed Astragalusand Oxytropisspp. Pyridine Cattle, horses, pigs, sheep CNS toxin; birth defects tobacco Nicotianaspecies 1CNS = central nervous system 448 JOURNAL OF RANGE MANAGEMENT54(4), July 2001 Table 3. Major locoweed species containing indolizidine alkaloids, primary distribution in the western U.S., and range of swainsonine concentration (mg/g dry weight). Range in Scientific name1 Common name Distribution Concentration Astragalus ----(mg/g)---- allochrous rattleweed southern California east to Texas 0.7 to 11.52,3 bisulcatus two-grooved milkvetch southern Canada south to New Mexico 0.0 to 0.42,3 drummondii Drummond milkvetch southern Canada south to northern N.M. 0.603 emoryanus red-stemmed peavine Utah and southwestern states into Texas 0.5 to 14 lentiginosus freckled milkvetch western Canada to California; Rocky 0.05 to 0.43,6,7 Mountains south into Arizona to Texas lonchocarpus great rushy milkvetch Nevada, Utah, Colorado, and southwestern 0.0 to 4.42,3,5 states missouriensis Missouri milkvetch southern Canada south to New Mexico 0.12 to 0.182,3 and Texas mollissimus woolly locoweed Utah and Wyoming south to Mexico 0.02 to 10.32,4,5,6 praelongus stinking milkvetch Utah, Nevada, Colorado and southwestern 0.03 to 0.22,3,5 states east into Texas tephrodes ashen milkvetch Nevada, southwestern Utah and New Mexico, 0.0 to 0.92,3 Arizona, and California Oxytropis lambertii Lambert’s locoweed southern Canada south to Arizona and 0.2 to 1.02,5 New Mexico sericea whitepoint locoweed northwest Canada south to Nevada, New 0.05 to 1.23,5,7 Mexico and Oklahoma 1Many species have one or several varieties, but that level of detail is beyond the scope of this paper 2Smith et al. 1992 3Fox et al. 1998 4Davis et al. 1984 5R.J. Molyneux, personal communication 6D.R. Gardner, personal communication 7Molyneux et al. 1989 Oxytropisspecies have been found to con- Elbein 1989). These accumulated old result in similar etiology and further tain swainsonine (Table 3). Many of these oligosaccharides damage cells in thyroid, increases in dosage do not increase the toxic species are located around the brain, pancreas, and kidney tissue, charac- severity of intoxication (Stegelmeier et al. Colorado Plateau, the Great Basin, and terized as foamy cytoplasmic vacuolation 1995a); however, this threshold is low and portions of the Great Plains. Some (Van Kampen and James 1970, relatively small doses have been shown to Astragalus species contain nitro-toxins Stegelmeier et al. 1995a). Inhibition of produce both clinical and histologic (e.g., Astragalus miser Dougl. ex Hook; Golgi mannosidase II results in abnormal lesions. For example, sheep were intoxicat- see Majak and Benn, this volume) or sele- glycosylation of proteins, affecting hor- ed with average daily swainsonine doses of nium (e.g., Astragalus bisulcatus (Hook.) mones, membrane receptors, and enzymes 0.21 mg/kg body weight/day (as ingested Gray). Other genera worldwide contain throughout the body. Once a sufficient plant material, Pfister et al. 1996b). swainsonine, including Swainsona spp. number of cells are damaged, signs of Swainsonine is water-soluble, and is (Colegate and Dorling 1997) and Ipomoea poisoning are seen, which may occur with- rapidly excreted (Stegelmeier et al. (Molyneux et al. 1995). Within the U.S., in 3 weeks (Van Kampen and James 1995b). Clearance time (T ) for swain- 1/2 Ipomoea spp. (morning glory) have not 1970). Microscopically, damage in the sonine from most tissues is about 20 been examined for swainsonine, but CNS results from vacuolar degeneration of hours; however, for the liver and kidneys Ipomoea batatas (L.) Lam. (sweet potato) both neurons and glia (Stegelmeier et al. it is much longer and requires about 60 can be toxic to livestock through an unre- 1994). Pathological lesions appear within hours. Swainsonine is distributed through- lated mechanism. 1 week after locoweed feeding begins out all tissues and is present in many ani- (Van Kampen and James 1970), and when mal products. Thus, current recommenda- Mechanism of Intoxication locoweed feeding ceases, the cytoplasmic tions are that animal products not be used, Swainsonine has a chemical structure vacuoles disappear quickly (James and and intoxicated animals withheld from similar to mannose and glucose, and this Van Kampen 1971). Residual CNS lesions slaughter for about 8 days after animals similarity may be the basis of its toxicity may resolve quickly depending on the discontinue locoweed ingestion (T1/2 x (Colegate et al. 1989). Swainsonine extent of intoxication (Pfister et al. 10; Stegelmeier et al. 1998a). Lactating inhibits several intracellular mannosidase 1996b), but once a particular threshold is animals that eat locoweed will excrete enzymes responsible for cleaving sugar exceeded, CNS damage becomes perma- swainsonine into the milk within 30 min molecules from oligosaccharides (Broquist nent (James and Van Kampen 1971), and (Broquist 1986); therefore nursing young 1986). Inhibition of ∝-mannosidase and the animal likely will display long-term may become intoxicated (James and subsequent failure to trim mannose from abnormal behavior (Pfister et al. 1996b). Hartley 1977). oligosaccharides, results in accumulation There appears to be a dose-response of mannose-rich oligosaccharides in lyso- threshold for swainsonine, such that Clinical Signs somes and causes cellular disruption, and incomplete enzyme inhibition occurs at The symptoms of locoweed poisoning eventual cell death (Dorling et al. 1989, lower doses. Doses at or above the thresh- are lethargy, muscular incoordination, JOURNAL OF RANGE MANAGEMENT54(4), July 2001 449 intention tremors, nervousness, and had seizures that severely disrupted pre- should not over-stock or over-utilize excitability, progressing to emaciation, hension and mastication. The loss of body locoweed-infested ranges, and should man- possible maniacal behavior when stressed, condition may also be a direct result of age for sufficient desirable forage so that and death. Horses may be particularly sus- swainsonine on hormonal and digestive grazing pressure does not impel livestock ceptible to intoxication (James and Van functions (Stegelmeier et al. 1995a). Both to begin eating locoweed. When animals Kampen 1971) and may be dangerous aspects probably operate simultaneously become overtly intoxicated, the most eco- when handled. Abortions and water belly to cause weight loss, because weight loss nomical solution may be to remove them (i.e., hydrops amnii) often occur when is not fully attributable to lower food from pasture, and allow time for recovery pregnant animals eat locoweed (Ralphs et intake (Velastegui et al. 1992). before selling (Torell et al. 1999b). al. 1994b). If the fetus survives in utero Mildly or moderately intoxicated ani- intoxication, the newborn offspring often mals can be salvaged and returned to near Whitepoint locoweed (Oxytropis exhibits abnormal suckling behavior, and normalcy by removing them from sericea) may not survive (Pfister et al. 1993). locoweed, and offering supplements Whitepoint locoweed begins growth in Grazing animals that consume locoweeds (Marsh 1909). This does not ensure that late winter and early spring on shortgrass at higher elevations (e.g., > 2200 m) are such animals will be fully productive and prairie rangelands, and the green leaves increasingly susceptible to congestive normal, but they may regain sufficient are often more palatable than are dormant right heart failure (James et al. 1983). body weight to allow resale (Torell et al. grasses. Livestock readily consume green Locoweed poisoning may be diagnosed 1999b). Notwithstanding, severely intoxi- locoweed leaves during the spring when by determining if animals have been cated animals may not regain lost body cool-season grasses are just beginning exposed to locoweed, and by evaluating weight even with supplemental feeding, growth, and warm-season grasses are dor- clinical and pathological signs; affected and will never be productive no matter mant (Ralphs et al. 1993). Grazing of animals show typical overt signs of poi- how intensive the rehabilitation. whitepoint locoweed may cease when soning while living, and have pathological There are pervasive anecdotal accounts warm season grasses begin active growth lesions upon post-mortem examination. of addiction or of animals “seeking out” in early summer (Ralphs et al. 1993), or With living animals, definitive diagnostic locoweed in preference to other desirable livestock may switch diet selection to tests using serum can verify consumption forage. Marsh (1909) reported that other green locoweeds (Oxytropis lamber- of locoweed (Stegelmeier et al. 1995b). locoweed was addictive to various animals, tii Pursh, Ralphs unpublished data), if Serum tests are not very reliable, however, including mules, pigs and pronghorn ante- available. On mountain rangelands, cattle if suspected animals have not recently lope. Lewin (1931) described livestock prefer immature seed pods of whitepoint (i.e., within 2–3 days) been eating addiction to locoweed and to the locoweed, but may also eat mature pods locoweed, as serum swainsonine quickly Australian plant Swainsona, long before it and green leaves later in the summer, par- disappears, and enzyme concentrations was known that Swainsona and locoweed ticularly if grazing pressure is excessive. quickly return to normal ranges. Future contained the same toxin. Recent reports of (Ralphs 1987). In contrast to shortgrass work will determine if other diagnostic toxicity in South America (Peru and prairie rangelands, whitepoint locoweed assays, such as determining glycosylation Brazil) from morning glory vines on high elevation rangelands is grazed of specific proteins, may be better indica- (Ipomoea spp.) indicate that livestock during summer even though other forage tors of intoxication. become addicted or dependent on these is also green and actively growing (Ralphs plants (Molyneux, personal communica- et al. 1986, Ralphs et al. 1987, Ralphs Effects on Livestock Nutrition and tion; Tokarnia et al. 1992). Ralphs et al. 1987). Simple changes in grazing manage- Grazing Behavior (1990) reported that dried, ground white- ment can have profound positive impacts A dominant feature of locoweed poison- point locoweed (Oxytropis sericeaNutt. in on losses to whitepoint locoweed. For ing in livestock is gradual emaciation (i.e., T. & G.) was not addictive, but some ani- example, Ralphs et al. (1984) reported wasting, Marsh 1909), which may not mals habituated or become accustomed to reductions in cattle losses from over 20% cease when animals are removed from eating the plant material. The obsessive to less than 3% annually from a simple locoweed (James et al. 1969). In studies consumption that producers observe may change in grazing management. at our laboratory, rats, sheep, cattle, and result from locoweed being relatively more horses have all shown declines in food palatable than associated forage (Ralphs et intake and body condition while eating al. 1993), or alternatively, locoweed may Specklepod locoweed (Astragalus locoweed, and the wasting continued after have pharmacological properties that are lentiginosusDougl. ex Hook.) locoweed feeding ceased. Steers lost reinforcing (Pfister 1999). Limited studies with cattle and horses (Pfister unpublished data) suggest that, weight while grazing locoweed, and gains during spring, likelihood of animals eating did not resume for 45–60 days after Management and Control locoweed increases greatly when animals locoweed feeding ceased (Ralphs et al. Swainsonine usually occurs at very low begin to search avidly for newly growing 2000). Overtly intoxicated horses, when concentrations (0.01 to 0.3% of dry cool-season grasses (i.e., “chasing green”). removed from locoweed-infested pastures, weight) in locoweeds (Table 3), with much Cattle prefer dormant grasses to speckle- continued to decline in body condition of the toxin found in the seeds. pod locoweed (var. diphysus)during much over 4 weeks even though their appetites Fluctuations in swainsonine concentration of the spring, but once cattle begin eagerly did not diminish (Pfister unpublished as the plants mature have little effect on selecting green grass, they also begin eat- data). The loss of productive function may how much locoweed is eaten (Ralphs and ing still-green, but drying, locoweed. result directly from neurological damage Molyneux 1989). The growth habits of During winter, cattle will even eat toxic because of impaired ability to prehend and locoweed in relation to other available for- black stems from previous growing sea- masticate food (Ralphs et al. 1991b). ages generally determine if and how much sons (Ralphs et al. 1988). During spring, Ralphs et al. (1991b) reported that sheep of the plant is eaten. Livestock producers horses intensely search for green grass, 450 JOURNAL OF RANGE MANAGEMENT54(4), July 2001 Table 4. Characteristics, relative toxicity, and general concentration range of toxic alkaloids of the dominant larkspur species in the western U.S. Class/Species Typical height Elevation Associated plant Typical Alkaloid at maturity communities risk of losses1 concentration2 --(cm)-- --(m)-- --(mg/g)-- Tall Larkspurs D. glaucum 90–200 >2000 aspen, conifers, alpine meadows low 1–20 D. barbeyi 90-180 >2200 aspen, conifers, alpine meadow, moderate to severe 1–29 mountain brush, alpine tundra D. glaucescens 76–90 >2000 mountain meadows, sagebrush low to moderate 1–12 D. occidentale 90–180 >2000 mountain brush, sagebrush, low to severe 0–18 conifer, aspen Low Larkspurs D. nuttallianum 20–60 >1200 mountain brush, sagebrush, aspen, low to severe 2–4 conifer, mountain and foothill meadows D. bicolor 20–40 >800 mountain brush, sagebrush, low to severe — D. andersonii 10–60 >1200 desert shrub, mountain brush, low to moderate 1–4 sagebrush, pinion-juniper Plains Larkspur D. geyeri 40-80 >1500 desert shrub, mountain brush, low to severe 1-4 sagebrush shortgrass prairie 1The risk of losing cattle to these species is a subjective evaluation based on plant toxicity, numbers of grazing cattle threatened during the growing season, and the geographical distri- bution of the larkspur species.D. glaucescensis relatively more toxic late in the growing season compared to mature plants of the other species. 2These concentrations are general values, and were determined by examining numerous samples collected over the past 6 years at the Poisonous Plant Research Laboratory. The val- ues for low and plains larkspurs should be considered preliminary because they are based on small sample sizes. Multi-site and year analysis for low and plains larkspurs is ongoing (Gardner, unpublished data). For further references see review by Pfister et al. (1999). For concentrations in Canadian low larkspur, see Majak (1993). and simultaneously select green locoweed. that they will avoid toxic plants, including eat locoweed. Herbicidal control of Once horses begin to eat locoweed, con- locoweed, in future encounters (Ralphs et locoweed (Ralphs and Ueckert 1988, sumption may continue until they become al. 1997a). In this procedure, animals are McDaniel 1999) in some pastures can pro- very intoxicated. given a taste of the plant in a corral, then vide a relatively “loco-free” pasture for dosed via stomach pump with a solution of critical times. Herbicidal treatment for this lithium chloride (LiCl) at 200 mg/kg body specific purpose is often economical, even Woolly locoweed (Astragalus mollis- weight. The LiCl-induced illness is associ- though general spraying to eliminate simusTorr.) ated with the taste of the toxic plant, and locoweed on a ranch-wide basis is usually Woolly locoweed is not very palatable animals avoid eating the target species not economical (Torell et al. 1999a). to grazing cattle, and probably is not (Ralphs 1992). Averted animals must not selected by livestock unless grazing pres- be allowed to graze with non-averted com- sure is excessive (Ralphs et al. 1993). panions, as social facilitation can quickly Diterpenoid alkaloids Consumption of woolly locoweed appears extinguish the aversion (Ralphs 1997). to cease with the growth of warm-season grasses (Ralphs et al. 1993). Major Plant Species Cyclic or “on-off” grazing Toxic C and C norditerpenoid alka- 19 20 Livestock can be poisoned by low level loids occur primarily in 2 genera from Social facilitation locoweed doses given for as little as 4 Ranunculaceae: larkspurs (Delphinium When some animals begin to eat weeks (Pfister et al. 1996b). Nonetheless, spp.) and monkshood (Aconitum spp.). locoweed, these ‘locoeaters’ can influ- ence other grazing animals, including considering both swainsonine’s rapid There are over 50 species each of nursing calves, to begin eating locoweed clearance and dose-response threshold, it Delphinium and Aconitum, but only a few through social modeling (Ralphs et al. may be possible to expose animals briefly are known to cause livestock poisoning. to locoweed with a low-risk of intoxica- 1994a). In most situations, ranchers should Monkshoods are highly toxic plants, but tion, if they are then allowed to recover on remove animals that eat locoweed to elim- we believe that most reports of livestock locoweed-free ranges. Recent work with inate social influences, and to prevent pro- losses to monkshood are attributable to sheep (Stegelmeier unpublished data) gressive intoxication. Some producers in larkspur (Knight and Pfister 1997). The 2 shows that animals repeatedly given New Mexico with locoweed-infested pas- plants grow together in wet mountain habi- locoweed for 10 days with a 14-day recov- tures have reduced their locoweed losses tats and are easily confused; furthermore, ery period had no detectable permanent by systematically, over several years, monkshood is not usually grazed by cattle. damage. On-off grazing schemes may removing any cow from their herds seen Larkspurs are divided into 3 general cate- work, but must be approached with cau- eating locoweed, before the animal either gories based primarily on mature plant tion as they have not been tested under becomes intoxicated or influences her calf height and distribution: low, tall, and field situations. or companions to eat locoweed (D. plains (Table 4). Most research has Graham, personal communication). focused on tall larkspurs (Pfister et al. Herbicidal control 1999). Livestock losses in the western Producers should, if possible, provide a Aversive Conditioning United States to all types of larkspurs prob- locoweed-free pasture for spring or fall Grazing animals may be conditioned so ably exceed $10 million dollars annually. grazing when animals are most likely to JOURNAL OF RANGE MANAGEMENT54(4), July 2001 451 Toxic Alkaloids and Occurrence Dobelis et al. 1999). Animals usually die trembling, but will be able to walk and Larkspurs contain many (> 18) norditer- from respiratory failure (i.e., asphyxiation) graze. Severely-intoxicated animals will penoid alkaloids of which the most toxic when the muscles of the diaphragm are be laterally-recumbent, and will be unable are methyllycaconitine (MLA), 14- paralyzed or the CNS respiratory center is to do more than thrash about. Marsh et al. deacetylnudicauline (DAN), and nudi- depressed. Larkspur alkaloid binding to (1916) reported that bloat seldom occurs cauline (NUD; Manners et al. 1993, nAch receptors appears to be correlated to in intoxicated animals, but our observa- 1995). Both MLA and DAN occur to some toxicity in various tissues (Kukel and tions suggest that bloat can be a significant extent in all classes of larkspurs, whereas Jennings 1994), and may explain sheep component of larkspur fatalities. Bloating NUD has not been found in tall larkspurs. tolerance to larkspur if larkspur toxins may occur as a result of paralysis of the A fourth alkaloid, deltaline, is relatively bind less avidly to nAch receptors in sheep rumen eructation (belching) mechanism. low in toxicity, but is the dominant alka- (Stegelmeier et al. 1998b). Cattle may die from bloat alone or asphyx- loid in most tall larkspurs, comprising ≥ Toxicity, but not lethality of MLA + iation from aspirated rumen contents while 40% of the alkaloid composition, while DAN has been established for cattle by recumbent from larkspur paralysis. Some MLA and DAN together comprise another oral doses of dried tall larkspur (Pfister et success of early remedies for larkspur poi- 20 to 50% of the alkaloid mix in tall lark- al. 1994b, 1997a). Cattle typically show soning (e.g., bacon fat and turpentine spurs. The MLA is the dominant alkaloid clinical signs when given an MLA + DAN given orally, Glover 1906) may have been in low larkspurs (Majak et al. 1987, Majak dose of about 20 mg/kg body weight due to bloat reduction. and Engelsjord 1988, Bai et al. 1994). (Pfister and Cheney 1998). A 450 kg cow The concentration of MLA and DAN is may show clinical signs after rapidly eat- Diagnosis and Treatment highest in immature larkspurs (Pfister et ing 1.8 kg of tall larkspur (≈ 7.2 kg wet Diagnosis of larkspur poisoning is usu- al. 1994a, Ralphs et al. 1997b). In tall weight). Assuming the plant material used ally by association, as dead or sick ani- larkspurs, MLA concentrations may in Olsen’s (1978) LD50 study (vegetative mals are found near larkspur plants. exceed 20 mg/g. In a Canadian study, and early flowering tall larkspur) con- Because larkspur poisoning causes no tis- Majak (1993) reported high concentrations tained 12 mg/g of toxic alkaloid, the LD50 sue lesions, pathological examination can of MLA (up to 8.7 mg/g) in vegetative low of MLA + DAN in cattle would be about only rule out other possible causes of larkspurs, and 2 mg/g in flowering plants. 30 mg/kg. Early studies by Marsh et al. death. Currently, no field test exists to Before shattering, tall larkspur pods are (1916) suggest that the lethal dose is lower determine if animals have been poisoned relatively high in toxicity (MLA + DAN = when tall larkspur is given repeatedly over by larkspur. Blood or rumen fluid may 7 to 12 mg/g). Toxicity declines rapidly in 3 to 4 days. contain larkspur alkaloids (Holstege et al. tall larkspurs once pods begin to shatter 1996); even so, cattle can eat substantial (Gardner and Pfister 2000), whereas con- Clinical Signs quantities of larkspur without ill effect, centrations are relatively stable in low Clinical signs of intoxication include and the presence of alkaloids in body flu- larkspurs after the vegetative stage (Majak muscular weakness and trembling, strad- ids only suggests larkspur intoxication. 1993, Gardner, unpublished data). dled stance, periodic collapse into sternal A variety of remedies have been applied recumbency, respiratory difficulty, and by ranchers (e.g., bleeding by cutting the Mechanism of intoxication finally death while in lateral recumbency. tail), but most are without scientific ratio- The primary result of larkspur toxicosis Moderately-intoxicated animals will peri- nale. Treated animals probably survive in livestock is neuromuscular paralysis, as odically collapse while moving, and be in because they did not eat a lethal dose of nicotinic acetylcholine (nAch) receptors in sternal recumbency for 10 to 30 min; larkspur and did not bloat. Drugs that the muscle and brain are blocked by MLA when the temporary paralysis subsides, increase acetylcholine concentration at the and related alkaloids (Aiyar et al. 1979, affected animals may show muscular neuromuscular junction have potential for Table 5. Relative pyrrolizidine alkaloid (PA) concentration and toxicity of various PA-containing plant species on western U.S. rangelands. Scientific name Common name Distribution Concentration1 Lethal Dose2 ---mg/g--- ---mg/g---. Cynoglossum officinale houndstongue widespread weed in North America 0.5 to 213 5 to 604 Senecio longilobus threadleaf groundsel midwest south into Texas and west into 1 to 875 10 to 136 New Mexico and Arizona riddellii Riddell’s groundsel midwest south into west Texas and New Mexico 2 to 1805 15 to 457 jacobaea tansy ragwort weed in northwestern U.S. 0.2 to 95 2 to 38 vulgaris common groundsel weed in western U.S. 2 to 35 Not available 1The concentration of total pyrrolizidine alkaloids (N-oxide and free base) in dry plant material. Concentrations vary greatly depending on growing conditions and plant part. The high value for S. riddellii (180 mg/g) is the highest recorded concentration of any type of alkaloid in any plant yet recorded (Molyneux and Johnson 1984). 2Lethal dose may be acute (short-term) or chronic (long-term) depending on dose, because toxicity from pyrrolizidine alkaloids may be delayed by weeks or months from the time animals ingest the plant. 3Pfister et al. 1992; Van Damm et al. 1994 4Baker et al. 1991; Stegelmeier et al. 1996 5Johnson et al. 1985a; Molyneux and Johnson 1984 6Johnson and Molyneux 1984 7Johnson et al. 1985b; Molyneux et al. 1991 8Johnson and Smart 1983 452 JOURNAL OF RANGE MANAGEMENT54(4), July 2001 reversing larkspur toxicity. The choliner- rapidly, and leaf toxicity is low (Gardner Herbicidal Control gic drug, physostigmine (0.08 mg/kg i.v.), and Pfister 2000). Larkspur losses can be economically has been successfully used under field and reduced if dense larkspur populations are pen conditions to reverse clinical larkspur controlled by herbicides. Picloram, met- Low larkspur (D. nuttallianum Pritz.) and intoxication (Nation et al. 1982, Pfister et sulfuron, and glyphosate have proven to Plains larkspur (D. geyeriGreene) al. 1994c). Our current recommendation is be effective in killing tall larkspurs when Consumption of low larkspur by cattle that ranchers not attempt to move partial- applied at specific growth stages appears to increase once low larkspur has ly-paralyzed or recumbent animals, as (Mickelsen et al. 1990, Ralphs et al. flowered, and higher grazing pressure will stress is detrimental. If intoxicated ani- 1991c, 1992). These herbicides do not increase amounts of low larkspur eaten mals bloat, passing a stomach tube or reduce toxic alkaloid concentrations in (Pfister and Gardner 1999). Spring graz- puncturing the rumen with a knife or tro- treated larkspur plants, and metsulfuron ing of low larkspur-infested ranges can be car will relieve gas pressure. may increase toxicity (Ralphs et al. 1998). problematic, as there may not be sufficient Therefore, sprayed areas should not be forage growth to graze these ranges before grazed until larkspur has withered and Impacts on Animal Nutrition and larkspur flowers, but risk appears to decomposed. Behavior increase once flowering occurs. Larkspur poisoning is acute, rather than Fortunately, in most years low larkspurs chronic, thus, animals that survive show are short-lived, so producers must avoid Pyrrolizidine Alkaloids essentially no long-term detrimental heavily infested areas for about 4 weeks effects. Ingestion of larkspur at sub-acute during peak toxicity. Four years of grazing doses has no negative impact on ruminal studies on plains larkspur-infested ranges Major Plant Species fermentation or digestive function (Pfister have shown few distinct patterns of con- Pyrrolizidine alkaloids (PAs) occur on et al. 1989). Larkspur poisoning probably sumption by lactating cows (Pfister, western U.S. rangelands primarily in has no long-term effect on diet selection or unpublished data). Senecio spp. (Asteraceae), and in grazing behavior, although previously-poi- Cynoglossum officinale L., (hound- soned animals eat less larkspur and other stongue, Boraginaceae). In the southeast- Other Management Options forage for a few days after a toxic episode ern U.S., Crotalaria spp. (Fabaceae) also Aversive Conditioning (Pfister et al. 1997a, Pfister and Cheney contain pyrrolizidine alkaloids. Cattle can be trained to avoid eating tall 1998). Eventually, larkspur consumption Worldwide, PAs are probably the most larkspur through aversive conditioning returns to previous levels, and animals economically-important plant toxins (Ralphs 1997), as previously noted with may be intoxicated again. impacting human health, as PAs contami- locoweed. Social facilitation, whereby one nate grain for poultry, ruminant, and non- animal influences another to eat a particu- ruminant livestock, and human consump- Grazing Management lar plant, will quickly extinguish the aver- tion, as well as herbal teas (Huxtable Tall larkspur (D. barbeyi Huth and D. sion, thus, averted cattle must be grazed 1989). About 3% of the flowering plants occidentale(Wats.) Wats.) separately from non-averted cattle (Lane in the world (> 6000 species) contain PAs Cattle eat little or no tall larkspur before et al. 1990, Ralphs 1997). Animals experi- (Smith and Culvenor 1981), and there are the plant has elongated flowering racemes enced in eating larkspur may also be suc- currently nearly 300 individual known (Pfister et al. 1988a, 1997b). Cattle gener- cessfully averted, although the aversion is PAs (Roitman and Panter 1995). The alka- ally begin consuming tall larkspur after initially more difficult to induce and may loid concentrations in range plants and flowering racemes are elongated, and con- be more fragile and less persistent than for subsequent toxicity vary widely (Table 5). sumption increases as larkspur matures. naive animals (Ralphs 1997). Consumption usually peaks during the pod stage of growth in late summer, when cat- Grazing Sheep Before Cattle Mechanism of intoxication tle may eat large quantities (25 to 60% of Marsh et al. (1916) recommended that The PAs occur in either the free-base or diet, Pfister et al. 1988b). ranchers graze sheep before cattle to take N-oxide form in plants, but neither of The period of greatest risk on tall lark- advantage of the low toxicity to sheep, and these forms is toxic to animals per se spur ranges extends from the flower stage Aldous (1917) noted that sheep grazing on (Winter and Segall 1989). The toxicity of into the pod stage. Many ranchers typical- immature D. occidentale in Nevada had PAs is due to the formation of toxic ly defer grazing on tall larkspur-infested reduced the poisoning risk to cattle. On metabolites in the liver termed pyrroles. ranges until the flower stage to avoid tall larkspur-infested ranges where lark- Pyrroles are formed as a detoxification death losses. This approach wastes much spur grows as discrete patches, sheep can intermediate through the action of liver valuable forage, and often places cattle be herded into or bedded on the patches to enzyme systems, primarily mixed function into larkspur-infested pastures when risk reduce larkspur availability or acceptabili- oxidases (MFOs), but the exact mecha- of losses is high. An additional 4 to 6 ty to cattle (Ralphs et al. 1991a, Ralphs and nism is not clear (Winter and Segall weeks of grazing may be obtained by Olsen 1992). In those areas where larkspur 1989). Pyrroles form adducts within the grazing these ranges early, before larkspur is uniformly spaced over a pasture, sheep liver with hepatic proteins and nucleic elongates flowering racemes (Pfister et al. must eat immature larkspur and leave suffi- acids, and damage liver cells, causing 1997b). The risk of losing cattle is low cient feed for cattle. This can be problemat- enlarged hepatocytes, abnormal bile secre- when grazing before flowering even ic, because early growth tall larkspur may tion, and fibrosis (Stegelmeier et al. 1996). though larkspur is very toxic, because not be palatable to sheep (Ralphs et al. A dysfunctional liver leads to other syn- larkspur consumption is very low. Once 1991a). Sheep grazing has successfully dromes such as chronic wasting disease pods are mature and begin to shatter, lark- reduced cattle losses on ranges with D. and photosensitization. The PAs can also spur ranges can usually be grazed with glaucescens in southwestern Montana (J. cause lesions in the lungs and brain. impunity because pod toxicity declines Helle, personal communication). JOURNAL OF RANGE MANAGEMENT54(4), July 2001 453 Clinical Signs and Diagnosis behavior directly. For example, horses tongue when other forage was adequate Poisoning from PAs may be either acute may show typical “head pressing” behav- (Pfister unpublished observations). When (high-dose and short-term) or chronic ior as a result of ammonia toxicity from houndstongue contaminates hay, it is read- (lower-dose and long-term). Acute intoxi- liver damage (Cheeke 1989). Intoxicated ily eaten by cattle and horses, and is quite cation is less common, as most animals animals may become intractable and diffi- toxic (Baker et al. 1989). poisoned by PAs develop clinical signs cult to handle as the disease progresses; in slowly over many weeks or months the final stages of poisoning animals may Quinolizidine Alkaloids (Cheeke 1989). Acute intoxication can stagger greatly. Liver damage can lead to kill animals within 1 day if sufficient plant secondary photosensitization, and as material is ingested (Baker et al. 1991). affected animals are sensitive to sunlight, Major Plant Species Chronic intoxication usually results from they become solitary and spend excessive The most problematic plant genera with ingestion of the PA-containing plant for amounts of time seeking shade instead of quinolizidine alkaloids is Lupinus several weeks (Baker et al. 1991, grazing. Severe sunburn may occur espe- (Fabaceae). Although lupine is cultivated Stegelmeier et al. 1996). Typical clinical cially on exposed areas such as the nose, in some parts of the world as forage or signs include depression and lethargy, vulva, udder, etc. Photosensitized, lactat- grain (so-called sweet lupine), in the west- anorexia, and ascites (fluid accumulation ing cows will often develop very inflamed ern U.S. many wild lupine species are in abdomen). None of these signs are spe- and sensitive udders, especially light-pig- toxic to livestock because of high alkaloid cific for PA–induced toxicity, thus, the mented animals, and will prematurely concentrations (Keeler 1989). Wink et al. diagnosis is usually made from a liver wean their nursing young. (1995) recently reported on the alkaloid biopsy and associated histopathology. concentration of 36 lupine species from Enlarged liver cells were the dominant Management and Control North America; most contain quinolizidine lesion seen in horses 6 months after they Senecio species alkaloids, but a few also contain piperidine were dosed with a low dose of alkaloids. Managing rangelands so that plant com- alkaloids or both types of alkaloids. Serum chemistry changes may be dramat- munities are in good condition and ade- ic, as many liver enzymes are altered, but quate forage is available is crucial to Mechanisms of Intoxication these changes are also not specific for PA- reducing losses to Senecio spp. (Merrill poisoning. Wasting disease (i.e., severe Quinolizidine alkaloids are both toxic and Schuster 1978). Generally, senecios emaciation) as a result of liver damage is and teratogenic (i.e., causing birth defects) are not very palatable, and are avoided by commonly noted, as is “hard, yellow to livestock (Panter and James 1995). grazing livestock if other forage is avail- liver” disease; all these conditions may be Lupines cause respiratory failure in sheep able. Drought stress and overgrazing can related to PA-induced damage to the liver, (Kingsbury 1964), but the mechanism is increase populations of threadlleaf ground- but can be caused by other toxic plants unknown. Lupine alkaloids bind differen- sel, as the plant is an aggressive invader and diseases (Stegelmeier et al. 1996). tially to both nicotinic and muscarinic Ach (Sharrow et al. 1988). Drought is an espe- Younger animals are more susceptible receptors (Schmeller et al. 1994), and cially dangerous time because other forage + + toPA-induced toxicosis because the higher affect Na and K ion channels (Wink et may be lacking and the toxic alkaloid con- metabolic activity of growing liver tissue al. 1995), but a specific relationship to centration in senecio plants increases dur- encourages pyrrole formation and results toxicity has not been developed. Birth ing drought (Molyneux and Johnson in more extensive liver damage (Cheeke defects are apparently caused by the 1984), so grazing animals may ingest high- 1989). The PAs are transferred in milk to effects of 2 different, but related, alka- er quantities of more toxic forage. Senecio nursing young, and there is a danger of loids, anagyrine (a quinolizidine alkaloid, species are also most toxic when plants are human consumption via milk (Molyneux Table 6) and ammodendrine (a piperidine reproducing, thus avoiding pastures when and James 1990). There are marked alkaloid; Panter et al. 1992). For unknown these plants are in bud, flower, or seed is species differences in tolerance for PAs, as reasons, cattle are uniquely sensitive to the prudent. Proper grazing management must goats and sheep are relatively more resis- effects of anagyrine, and ingestion of alka- consider stocking rates, as improper stock- tant to PA-poisoning than cattle and horses loid-rich lupine causes the condition ing may increase the amount of toxic plant (Cheeke and Huan 1995). Detoxification of “crooked calf disease” in bovine offspring consumed when alternative forages PAs occurs to a limited extent in the rumen (Table 6, Keeler 1989, Panter et al. 1994). become limited. Excessive stocking may (Wachenheim et al. 1992), but the liver Crooked calf disease has been associated lead to degradation of the desirable plant appears to be the major site of detoxifica- with Lupinus laxiflorusDouglas ex Lindl., community allowing Senecio species to tion (Cheeke 1994). L. caudatusKellogg, and L. sericeaPursh increase. Herbicidal control may alleviate (Panter et al. 1992). Crooked calf disease some problems if incorporated into an is caused by reductions in fetal movement Impacts on Animal Nutrition and overall management program (Sharrow et during a susceptible period in gestation Behavior al. 1988). (Panter et al. 1988a). This reduction in Poisoning by PAs clearly has a great fetal movement at the critical time is likely impact on the nutrition of grazing and pen- Houndstongue (Cynoglossum officinale) to interfer with bone, muscle and ligament fed animals. Animals with compromised Houndstongue is not only a toxic plant, development, resulting in mild to lethal liver function will generally show slow but also a noxious weed that is increasing skeletal malformations and cleft palate in weight loss over a long period of time in North America. The plant spreads from calves (Panter et al. 1990, 1988a). Even (perhaps years). Further, PA-intoxication bur-like seeds that cling to animals and though many calves are born alive, most may interfere with mineral and vitamin humans alike, and invades disturbed areas. of these deformities make them virtually nutrition to further degrade animal perfor- Houndstongue is generally unpalatable worthless, and most deformed calves are mance (Cheeke 1989). when growing on rangelands, but we have destroyed shortly after birth. Intoxication by PAs can affect animal observed lactating cows eat green hounds- 454 JOURNAL OF RANGE MANAGEMENT54(4), July 2001 Table 6. Potentially teratogenic Lupinus species nutritional properties and to reduce their Washington, Oregon, Idaho, and Montana, on western U.S. rangelands1. Ingestion by alkaloid content for both livestock and causing severe losses. For example, pro- pregnant cattle of Lupinus species with ter- human consumption (Aniszewski 1993). ducers in Adams County, Washington lost atogenic alkaloids (quinolizidine or piperi- Lupines, being legumes, may contain > over 30% of their calves (> 4000 calves) dine) from gestation day 40–100 may cause 20% crude protein (Panter et al. 1999). from lupine-caused birth defects (Panter et severe deformities in calves (i.e., crooked calf disease). So-called “sweet” lupines are relatively al. 1999). low in alkaloid concentrations, and are an Scientific name Common name excellent source of protein for livestock (Stanford et al. 1996). Range-grown Piperidine Alkaloids Lupinus albicaulis pine lupine lupines, particularly the seed pods, are a albifrons white face lupine good source of nutrition if they are low Major Plant Species alpestris mountain silvery lupine enough in alkaloids that toxicity problems Piperidine alkaloids are broadly distrib- andersonii Anderson’s lupine do not develop (Panter et al. 1999). argentous silvery lupine uted in nature, but only a few range plants arbustus2 spur lupine have sufficient amounts to cause toxicity bakeri2 Management and Control problems for domestic livestock. Several burkei Burke’s lupine Losses of livestock from lupine poison- Lupinusspecies (Fabaceae) contain piperi- caudatus tailcup lupine ing can largely be prevented by under- dine alkaloids (Table 6), in addition to densiflorus standing 2 interrelated aspects. First, the quinolizidine alkaloids (Roitman and Panter elatus elagans highest concentrations of toxic alkaloids 1995). The suspected toxic piperidine alka- excubitus tend to occur in immature lupine plants loids in Lupinusare ammondendrine and N- erectus tall silvery lupine and seed pods. Anagyrine concentrations methyl hystrine (Panter and James 1995). evermannii Everman’s lupine are highest (> 5 mg/g) in early growth, Recently, 8 yearling steers died after eating formosus2 Lunara lupine and decline to less than 0.5 mg/g after Lupinus argenteus Pursh containing high holosericeus seed shatter, except that concentrations levels of ammondendrine and N-methyl humicola lowland lupine latifolius broadleaf lupine increase when lupine seeds ripen (Keeler ammodendrine (Panter, personal communi- laxiflorus looseflower lupine 1976). Second, pregnant cattle are suscep- cation). These cattle began grazing L. leucophyllus velvet lupine tible to the teratogenic effects of alkaloids argenteusafter grasses were depleted. longifolius during a window from days 40 to 70 of The most prominent species containing montigenus Mt. Rose lupine gestation, occasionally extending to 100 piperidine alkaloids is poison hemlock nootkatensis Nootka lupine (Alaska) days (Panter et al. 1997). Birth defects in (Conium maculatumL., Apiaceae). Only 1 polyphyllus Washington lupine rivularis stream lupine cattle can be prevented by using breeding species of Conium grows in North ruber red lupine or grazing programs that avoid placing America, and should not be confused with sericeus silky lupine pregnant cattle in lupine-dominated pas- water hemlock (Cicuta maculata L.). sulphureus yellow lupine tures in the first trimester of gestation Poison hemlock grows in disturbed areas, 1Adapted from Davis (1982), Davis and Stout (1986) and (Keeler et al. 1977, Panter et al. 1992, waste land, and along waterways, invad- Wink et al. (1995). Species were listed if they contain any 1999). Alternatively, risk can be reduced ing perennial hayfields and pastures. The of the quinolizidine alkaloid, anagyrine. 2These species contain piperidine alkaloids (e.g., ammon- by allowing only short-term access to first alkaloid ever characterized (coniine) dendrine) that are also teratogenic when eaten by cattle lupines by pregnant cattle in some form of was isolated from poison hemlock in 1827 (Panter et al. 1998b). rotational grazing scheme (Panter et al. (Panter and Keeler 1989). In addition to 1999). Herbicidal control of lupines is fea- coniine, poison hemlock contains 4 other Clinical signs sible (Ralphs et al. 1991d), but chemical alkaloids, of which the most toxic alkaloid Lupine toxicity is seen clinically as a control is usually more expensive than is ϒ-coniceine, the biogenic precursor for neurologic disease that progresses from altering a grazing management program. the other Conium alkaloids (Panter and depression and lethargy to muscular weak- Acute toxicity problems are less com- Keeler 1989). The ϒ-coniceine is about 8 ness, collapse, respiratory failure and mon now, but large sheep losses occurred times more toxic than coniine (Bowman death (Panter et al. 1999). Animals that frequently 100 years ago (Chesnut and and Sanghvi 1963, Panter et al. 1998a), survive for 1 or 2 days may recover com- Wilcox 1901). Deaths losses usually occur and this difference has important manage- pletely (Panter et al. 1999), or they may when livestock, usually sheep, ingest a ment implications. succumb several days later (Kingsbury large amount of seed pods in a short peri- 1964). Pregnant cows that eat small od of time (James et al. 1968). This can Alkaloid Occurrence amounts of lupine may not show clinical occur from contaminated hay or from hun- The alkaloid concentration and distribu- signs of intoxication, but give birth to gry animals gaining access to lupine-dom- tion of alkaloids in poison hemlock are deformed offspring (e.g., cleft palate, inated forage, and can be prevented by affected by many factors, including envi- Panter et al. 1994). While sheep, goats, using lupine-free hay and avoiding lupine- ronmental changes and plant maturity and cattle may show signs of acute lupine dominated ranges when other forage is (Cromwell 1956, Leete and Olson 1972). toxicity such as depression and death, the scarce. During some years, lupine popula- Drought stress increases total alkaloid anygyrine-containing lupines cause birth tions will temporarily expand on range- concentrations (Fairbairn and Challen defects in cattle only (Panter et al. 1998b). lands not normally problematic. Livestock 1959). Immature poison hemlock often producers need to be aware of lupine pop- has a high concentration of ϒ-coniceine, ulations and be sufficiently alert to alter Impacts on Animal Nutrition which may then be converted predomi- grazing or breeding programs when these Many lupines are not toxic to livestock, nately into coniine during active growth. and plant breeders have conducted exten- eruptions occur. Lupine populations During flowering, concentrations of ϒ-con- increased dramatically during 1997 in sive breeding programs to enhance lupines iceine also shift to coniine. Thus, coniine is JOURNAL OF RANGE MANAGEMENT54(4), July 2001 455 the major alkaloid in mature plants and toxicity is made from a knowledge of (Keeler 1979). Anabasine causes fetal seed, whereas ϒ-coniceine dominates the exposure to the plant, and from clinical malformations virtually indistinguishable alkaloid mix in early growth and fall signs. Additionally, many reports suggest from those caused by Lupinusand Conium regrowth. Leaves from young or regrowing that affected animals have a “mousy” odor (Panter and James 1995). plants contain 3 to 6 mg/g of toxic alka- on their breath or urine. Alkaloid screen- loids, whereas immature and mature fruit ing can detect the presence of poison hem- may contain > 10 mg/g (Cromwell 1956). lock alkaloids in body fluids, providing Steroidal (Veratrum-type) confirmation that animals were ingesting Alkaloids the plant (Galey et al. 1992). Mechanism of Intoxication Poison hemlock alkaloids act on both Major Plant Species smooth and striated muscle; the effect on Management and Control The steroidal veratrum-type alkaloids skeletal muscle is a curare-like neuromus- The most critical time of the year to are found primarily in Veratrum species cular blockage, similar to larkspurs. avoid poison hemlock is spring because (false hellebore) and Zigadenus species Unlike larkspur alkaloids, blockage occurs the plant often appears before other forage (death camas, Liliaceae). Western false- only after initial muscular stimulation has emerged. Green seed pods may be hellebore (Veratrum californicumDurand) (Bowman and Sanghvi 1963). When the eaten in mid-to-late summer (Panter and is the dominant species in the western dose is sufficient, the blockage causes Keeler 1989). Furthermore, poison hem- U.S., and occurs in moist mountain mead- muscular paralysis, resulting in depressed lock may regrow in fall after seed shatter. ows, and along slopes and stream banks. respiration. The specific site of blockage Ingestion during fall may coincide with Death camas grows on plains, prairies, and at the neuromuscular junction is not fetotoxicity in pregnant cattle, if they are foothill ranges throughout the western known, nor is the exact mechanism in the first trimester (days 30–75, Panter et U.S. There are several species of death (Panter and Keeler 1989). Poison hem- al. 1988b). If poison hemlock has invaded camas, and all should be considered toxic lock alkaloids are also potent teratogens, hay fields, the contaminated hay can poi- even though toxicity can vary within and and ingestion during pregnancy induces son livestock. Even though toxicity among species (Panter and James 1989). skeletal malformations that are virtually decreases upon drying, sufficient toxin indistinguishable from those caused by may be retained to poison livestock (Galey lupines (Panter et al. 1988b). The mecha- et al. 1992). Cattle appear to be particular- Alkaloids and Mechanism of nism of fetotoxicity is thought to be the ly susceptible because of their acceptance Intoxication same, namely reductions in fetal move- of the plant and their sensitivity to the ter- Veratrum species ment during critical phases of gestation atogenic alkaloids. Poison hemlock can be False hellebore has long been recog- (Panter et al. 1988a). easily controlled with phenoxy herbicides nized as a toxic plant for livestock (Hall (Panter et al. 1988b). and Yates 1915), although false-hellebore- Clinical Signs and Diagnosis induced fetotoxicity in sheep was not Poison hemlock causes initial CNS Impacts on Grazing Behavior reported until 1962 (Binns et al. 1962). stimulation with frequent urination and Poison hemlock is reported to be habituat- The primary teratogen is cyclopamine; the defecation, dilated pupils, increased heart ing or even addictive (Kingsbury 1964, closely-related alkaloid veratramine is rate, muscular weakness and trembling Panter and Keeler 1989). Goats (Copithorne very toxic but does not produce abnormal- and ataxia. This initial stage is followed 1937), cows (Penny 1953), and pigs (Panter ities (Keeler 1983). Ingestion of false by depression with further muscular weak- et al. 1985) readily eat fresh hemlock, even hellebore by pregnant sheep on gestation ness, collapse, and death due to respiratory when intoxicated. Panter (1983) reported day 14 results in “monkey-faced” or paralysis (Panter et al. 1988b). Although that intoxicated pigs “relished” the plant, cyclopian lambs with potentially severe animals exhibit tremors, muscular weak- and seemingly developed a craving for craniofacial defects (Binns et al. 1962). ness and collapse, they do not have true poison hemlock. The facial defects result from the toxic seizures and may recover quickly if a sub- insult to the neural tube such that the lethal dose was eaten. Although poison embryonic forebrain fails to divide nor- Related Pyridine Alkaloids hemlock is fetotoxic to pregnant animals mally. Veratrumalkaloids have a structur- as are lupines, Coniumis more universally Tree and wild tobacco (Nicotiana spp., al resemblance to cholesterol. Recent teratogenic, affecting cattle, sheep, goats, Solanaceae) are the primary toxic plants in work suggests that a disruption in choles- and pigs (Panter and Keeler 1989). Most the U.S. that contain pyridine alkaloids, terol transport within cells prevents brain pregnant animals that later develop terata closely related to piperidine alkaloids cells from recognizing signals to divide after ingesting poison hemlock also show (Roitman and Panter 1995). Several properly (Incardona et al. 1998). Other initial signs of acute toxicity, and many species of Nicotiana poison livestock in work suggests that cyclopamine may act are fatally intoxicated, unlike the teratoge- the western U.S. (Kingsbury 1964), by competitive binding at Ach receptors nesis from lupine alkaloids. The severity of including N. tabacum(Burley tobacco), N. (Keeler 1988). Other defects and fetal death birth defects varies according to the dose glauca (tree tobacco), N. trigonophylla are possible at later stages of gestation up and the animal species. Sheep are less sen- (wild tobacco) and N. attenuata (wild to 33 days (Keeler et al. 1986). Sheep are sitive than are cattle, goats, and pigs tobacco). Tree and wild tobacco plants are primarily affected because of their propen- (Panter et al. 1988b). Similar birth defects generally not palatable to livestock graz- sity to eat false hellebore but cattle and can be caused by genetic, traumatic, or ing on rangelands (Panter et al. 1992). goats are also susceptible. A single dose of other environmental toxins and the clinical These plants contain nicotine, a well- 1.5 g of purified alkaloid will cause defor- signs and lesions are nonspecific. Because known toxin, and more importantly, the mities in sheep (Keeler 1983). there are no definitive pathological teratogenic piperidine alkaloid, anabasine lesions, the diagnosis of poison hemlock 456 JOURNAL OF RANGE MANAGEMENT54(4), July 2001
Description: