Abstract

It is well known that several of the swainsonine-containing plant species found widespread around the world have a negative economic impact in each country. In Argentina, most of the information on the poisonous plant species that produce α-mannosidosis is published in Spanish and thus not available to most English-speaking researchers interested in toxic plants. Therefore, the aim of this review is to summarize the information about swainsonine-containing plants in Argentina, which are extensively distributed throughout different ecoregions of the country. To date, five species from three genera have been shown to induce α-mannosidosis in livestock in Argentina: Ipomoea carnea subsp. fistulosa, Ipomoea hieronymi subsp. calchaquina (Convolvulaceae), Astragalus garbancillo, Astragalus pehuenches (Fabaceae), and Sida rodrigoi (Malvaceae). These species contain the indolizidine alkaloid swainsonine, which inhibits the lysosomal enzyme α-mannosidase and consequently affects glycoprotein metabolism, resulting in partially metabolized sugars. The prolonged consumption of these poisonous plants produces progressive weight loss and clinical signs related to a nervous disorder, characterized by tremors of head and neck, abnormalities of gait, difficulty in standing, ataxia and wide-based stance. Histological lesions are mainly characterized by vacuolation of different cells, especially neurons of the central nervous system. The main animal model used to study α-mannosidosis is the guinea pig because, when experimentally poisoned, it exhibits many of the characteristics of naturally intoxicated livestock.

Key words
Argentina; guinea pig model; livestock; neuronal vacuolation; poisonous plants; swainsonine

INTRODUCTION

Several poisonous plants produce signs compatible with a nervous syndrome characterized by ataxia, muscle tremors, blindness, irritation, recumbency or coma, in the livestock consuming them (Odriozola 2015ODRIOZOLA E. 2015. Plantas y sustancias tóxicas para el ganado. Maskana 6: 149-161.). In some of these plants, the toxic principle is swainsonine (SW) (Figure 1a, b), an alkaloid not produced by the plant but by a fungal symbiont associated with the plant (Cook et al. 2014COOK D, GARDNER D & PFISTER J. 2014. Swainsonine-containing plants and their relationship to endophytic fungi. J Agri Food Chem 62: 7326-7334. doi:10.1021/jf501674r.). All the SW-containing species so far investigated have been found to be associated with a specific fungal symbiont (Braun et al. 2003BRAUN K, ROMERO J, LIDDELL C & CREAMER R. 2003. Production of swainsonine by fungal endophytes of locoweed. Mycol Res 107(8): 980-988. doi: 10.1017/S095375620300813X., Yu et al. 2010YU Y, ZHAO Q, WANG J, WANG J, WANG Y, SONG Y & LI Q. 2010. Swainsonine-producing fungal endophytes from major locoweed species in China. Toxicon 56(3): 330-338. doi: 10.1016/j.toxicon.2010.03.020., Baucom et al. 2012BAUCOM DL, ROMERO M, BELFON R & CREAMER R. 2012. Two new species of Undifilum, fungal endophytes of Astragalus (locoweeds) in the United States. Botany 90(9): 866-875. doi.10.1139/b2012-056., Gao et al. 2012GAO X, COOK D, RALPHS MH, YAN L, GARDNER DR, LEE ST & ZHAO ML. 2012. Detection of swainsonine and isolation of the endophyte Undifilum from the major locoweeds in Inner Mongolia. Biochem Syst Ecol 45: 79-85. doi: 10.1016/j.bse.2012.07.012., Cook et al. 2013COOK D, BEAULIEU WT, MOTT IW, RIET-CORREA F, GARDNER DR, GRUM D & MARCOLONGO-PEREIRA C. 2013. Production of the alkaloid swainsonine by a fungal endosymbiont of the Ascomycete order Chaetothyriales in the host Ipomoea carnea. J Agri Food Chem 61(16): 3797-3803. doi: 10.1021/jf4008423., Grum et al. 2013GRUM DS, COOK D, BAUCOM D, MOTT IW, GARDNER DR, CREAMER R & ALLEN JG. 2013. Production of the alkaloid swainsonine by a fungal endophyte in the host Swainsona canescens. J Nat Prod 76(10): 1984-1988. doi: 10.1021/np400274n.). Examples of these symbionts include the fungal genus Alternaria section Undifilum, which was isolated from locoweed from North America (Braun et al. 2003BRAUN K, ROMERO J, LIDDELL C & CREAMER R. 2003. Production of swainsonine by fungal endophytes of locoweed. Mycol Res 107(8): 980-988. doi: 10.1017/S095375620300813X.), and a Chaetothyriales associated with Ipomoea carnea from Brazil (Cook et al. 2013COOK D, BEAULIEU WT, MOTT IW, RIET-CORREA F, GARDNER DR, GRUM D & MARCOLONGO-PEREIRA C. 2013. Production of the alkaloid swainsonine by a fungal endosymbiont of the Ascomycete order Chaetothyriales in the host Ipomoea carnea. J Agri Food Chem 61(16): 3797-3803. doi: 10.1021/jf4008423.). In Argentina, the fungal genus Alternaria section Undifilum has been recently detected on Patagonian Astragalus (Martinez et al. 2019bMARTINEZ A, ROBLES C, ROPER J, GARDNER DR, NEYAZ MS, JOELSON NZ & COOK D. 2019b. Detection of swainsonine-producing endophytes in Patagonian Astragalus species. Toxicon 171: 1-6. doi.org/10.1016/j.toxicon.2019.09.020.).

Figure 1a
Representative structure of indolizidine alkaloid.

Figure 1b
Structures of the glycosidase-inhibitory alkaloids of the tropane found in the plant Ipomoea carnea.

SW inhibits the lysosomal α-mannosidase enzyme and Golgi mannosidase II. This occurs because SW has many similarities to the simple sugar mannose, which it appears to mimic (Dorling et al. 1978DORLING PR, HUXTABLE CR & VOGEL P. 1978. Lysosomal storage in Swainsona spp. toxicosis: an induced mannosidosis. Neuropathol Appl Neurobiol 4(4): 285-295., Colegate et al. 1979COLEGATE SM, DORLING PR & HUXTABLE CR. 1979. A spectroscopic investigation of swainsonine: an α-mannosidase inhibitor isolated from Swainsona canescens. Aust J Chem 32(10): 2257-2264.). The inhibition results in a complete blockage of complex molecules, and the failure of the trimming process results in an accumulation of undegraded oligosaccharides in lysosomes (Malm & Nilssen 2008MALM D & NILSSEN O. 2008. Alpha-mannosidosis. Orph J Rare Dis 3(1): 21. doi:10.1186/1750-1172-3-21.). Prolonged consumption of plants containing SW produces a lysosomal storage disease called acquired α-mannosidosis (Jolly & Walkley 1997JOLLY RD & WALKLEY SU. 1997. Lysosomal storage diseases of animals: an essay in comparative pathology. Vet Path 34(6): 527-548. https://doi.org/10.1177/030098589703400601.).

The term locoweed poisoning refers to the livestock poisoning by Astragalus and Oxytropis species. This poisoning is economically detrimental to the livestock industry in many countries, including China (Zhao et al. 2013ZHAO M, GAO X, WANG J, HE X & HAN B. 2013. A review of the most economically important poisonous plants to the livestock industry on temperate grasslands of China. J App Tox 33(1): 9-17. doi: 10.1002/jat.2789.), New Mexico and western United States (Ralphs et al. 2000RALPHS MH, GRAHAM D, DUFF G, STEGELMEIER BL & JAMES LF. 2000. Impact of locoweed poisoning on grazing steer weight gains. J Rang Man 53(1): 86-90. doi: 10.2307/4003397.), and Canada (Harries et al. 1972HARRIES WN, BAKER FP & JOHNSTON A. 1972. Case report: an outbreak of locoweed poisoning in horses in southwestern Alberta. Can Vet J 13: 141-145.). In the US, these losses have been estimated in several million dollars annually, due to death, abortion, reproductive problems, and lack of weight gain (James & Nielsen 1994JAMES LF & NIELSEN D. 1994. Locoweeds: assessment of the problem on western U. S. rangelands. In: James LF, Ralphs MH and Nielsen DB (Eds). The Ecology and Economic Impact of Poisonous Plants on Livestock Production. Boulder, Colo, USA: Westview Press, p. 171-180., Ralphs et al. 2000RALPHS MH, GRAHAM D, DUFF G, STEGELMEIER BL & JAMES LF. 2000. Impact of locoweed poisoning on grazing steer weight gains. J Rang Man 53(1): 86-90. doi: 10.2307/4003397.). In Argentina, five species from three genera have been shown to induce α-mannosidosis in livestock: Ipomoea carnea, I. hieronymi subsp. calchaquina (Convolvulaceae), Astragalus garbancillo, A. pehuenches (Fabaceae), and Sida rodrigoi (Malvaceae) (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384., Rodriguez Armesto et al. 2004RODRIGUEZ ARMESTO RR, REPETTO AE, ORTEGA HH, PERALTA CJ, PENSIERO JF & SALVETTI N. 2004. Intoxicación en cabras por ingestión de Ipomoea hieronymi var. Calchaquina en la provincia de Catamarca, Argentina. Rev Vet Arg 21: 332-341., Ríos et al. 2015RÍOS EE, CHOLICH LA, CHILESKI G, GARCÍA EN, LÉRTORA J, GIMENO EJ & TEIBLER GP. 2015. Suspected natural lysosomal storage disease from ingestion of pink morning glory (Ipomoea carnea) in goats in northern Argentina. J Vet Med Sci 77(7): 847-850. doi: 10.1292/jvms.14-0317. https://doi.org/10.1292/jvms.14-0317., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.,b). However, accurate statistics on animal losses due to consumption of these poisonous plants in Argentina are not yet available.

This review thus presents the available information about the distribution and habitat of SW-containing plants in Argentina, their toxicological aspects, as well as epidemiological and pathological findings from spontaneous and experimental cases of poisoning by consumption of these plants.

MATERIALS AND METHODS

Distribution, habitat and chemistry of the five SW-containing plants identified in Argentina

Ipomoea carnea (Jacq.) subsp. fistulosa (Mart. ex Choisy) (Family: Convolvulaceae; Figure 2a) is an evergreen shrub ≤ 3 m high, which propagates by stems capable of rooting within a few days. The stem is thick and develops into a solid trunk over several years, with many branches from the base. The flowers are pale pink, the fruits have a glabrous capsule, and the seeds are silky. The leaves are green, lanceolate and 10-25cm long (Chiarini & Ariza Espinar 2006CHIARINI F & ARIZA ESPINAR L. 2006. Flora fanerogámica Argentina: Programa ProFlora (Conicet). Angiospermae, Dicotyledoneae: 249. Convolvulaceae. Museo Botánico, IMBIV 96: 1-81.).

Figure 2a
Distribution of Ipomoea carnea subsp. fistulosa in Argentina.

Ipomoea carnea is found in subtropical and tropical regions, from Venezuela and Colombia to Argentina. In Argentina, it grows spontaneously in northeastern and central provinces, like Corrientes and Entre Ríos. However, it can also be found in cultivated soils of the provinces of Salta, Chaco, Formosa, Tucumán, Santiago del Estero and Córdoba (Figure 2a). This area corresponds to the “Chaco Húmedo” ecoregion, which is characterized by a wet and hot climate, with annual rainfall of 1275 mm and average temperatures between 22°C and 33°C in summer and between 12°C and 22°C in winter (Figure 3). Ipomoea carnea, locally called “Mandiyura” or “Aguapeı”, grows alongside wet grasslands (Haase 1999HAASE R. 1999. Seasonal growth of” algodão-bravo” (Ipomoea carnea spp. fistulosa). Pesq Vet Bras 34(2): 159-163.). In these areas, the main agricultural activity is the breeding of cattle, sheep and goats, under extensive grazing conditions (Caspe et al. 2008CASPE SG, BENDERSKY D & BARBERA P. 2008. Plantas tóxicas de la provincia de Corrientes. Instituto Nacional de Tecnología Agropecuaria. Serie Técnica, 43 p.).

Although in the last century the toxicity of I. carnea has been reported in different countries of the world (Daló & Moussatché 1978DALÓ N & MOUSSATCHÉ H. 1978. Acción tóxica de las plantas del género Ipomoea. Rev UCO 6: 25-39., Freire 1984FREIRE A. 1984. Notas colhidas na provincia do Ceará. Euzébio Martins Costa. Rev Farm 1: 155-160., de Balogh et al. 1999DE BALOGH KKIM, DIMANDE AP, VAN DER LUGT JJ, MOLYNEUX RJ, NAUDE TW & WELMAN WG. 1999. A lysosomal storage disease induced by Ipomoea carnea in goats in Mozambique. J Vet Diagn Inv 11: 266-273. doi:10.1177/104063879901100310.), in Argentina it was detected for the first time in 2007. Samples collected from Corrientes province showed concentrations of SW between 0.01% and 0.02% (Table I) (Cholich et al. 2009CHOLICH LA, GIMENO EJ, TEIBLER PG, JORGE NL & ACOSTA DE PÉREZ OC. 2009. The guinea pig as an animal model for Ipomoea carnea induced a-mannosidosis. Toxicon 54: 276-282. doi: 10.1016/j.toxicon.2009.04.012.), exceeding 10-20 times the concentration of 0.001%, which is considered poisonous for livestock (Molyneux et al. 1995MOLYNEUX RJ, MCKENZIE RA, O’SULLIVAN BM & ELBEIN AD. 1995. Identification of the glycosidase inhibitors swainsonina and calystegine B2 in weir vine (Ipomoea sp. Q6 aff. calobra) and correlation with toxicity. J Nat Prod 6: 878-886. doi:10.1021/np50120a009.). Ipomoea carnea also contains calystegines, which are hydroxylated nortropane alkaloids and potent glycosidase inhibitors (Asano et al. 1995ASANO N, KATO A, OSEKI K, KIZU H & MATSUI K. 1995. Calystegins of Physalis alkekengi var. francheti (Solanaceae). Structure determination and their glycosidase inhibitory activities. Eur J Biochem 229: 369-376. https://doi.org/10.1111/j.1432-1033.1995.0369k.x., de Balogh et al. 1999DE BALOGH KKIM, DIMANDE AP, VAN DER LUGT JJ, MOLYNEUX RJ, NAUDE TW & WELMAN WG. 1999. A lysosomal storage disease induced by Ipomoea carnea in goats in Mozambique. J Vet Diagn Inv 11: 266-273. doi:10.1177/104063879901100310.). However, according to Stegelmeier et al. (2008)STEGELMEIER BL, MOLYNEUX RJ, ASANO N, WATSON AA & NASH RJ. 2008. The comparative pathology of the glycosidase inhibitors swainsonine, castanospermine, and calystegines A3, B2, and C1 in mice. Tox Path 36(5): 651-659. doi:10.1177/0192623308317420., it is difficult to definitively prove the role of calystegines in the poisoning by plants containing mixtures of other toxins, as SW. The samples of I. carnea collected in 2007 also contained calystegines B1, B2, and C1 (Figure 1a,b), and trace amounts of calystegines A3 and B3, whose mean concentration was 0.05% (Table I) (Cholich et al. 2009CHOLICH LA, GIMENO EJ, TEIBLER PG, JORGE NL & ACOSTA DE PÉREZ OC. 2009. The guinea pig as an animal model for Ipomoea carnea induced a-mannosidosis. Toxicon 54: 276-282. doi: 10.1016/j.toxicon.2009.04.012.).

In Nicaragua, a recent outbreak of a neurological syndrome in goats was found to be associated with the consumption of Ipomoea trifida and I. carnea containing only calystegines, since all the samples studied were negative for SW, suggesting that SW is not the only toxin involved in Ipomoea poisoning (Salinas et al. 2019SALINAS LM, BALSEIRO A, JIRÓN W, PERALTA A, MUÑOZ D, FAJARDO J & GARCÍA MARÍN JF. 2019. Neurological syndrome in goats associated with Ipomoea trifida and Ipomoea carnea containing calystegines. Toxicon 157: 8-11. doi: 10.1016/j.toxicon.2018.11.291.). However, this is not supported by other studies, and there is a possibility that the samples analyzed were not representative of the plants that poisoned the goats. According to Cook et al. (2014)COOK D, GARDNER D & PFISTER J. 2014. Swainsonine-containing plants and their relationship to endophytic fungi. J Agri Food Chem 62: 7326-7334. doi:10.1021/jf501674r., SW concentration varies between plants of the same species and population.

Regarding the fungal symbiont, as mentioned above, a Chaetothyriales fungus has been identified in Brazilian SW-producing I. carnea (Cook et al. 2013COOK D, BEAULIEU WT, MOTT IW, RIET-CORREA F, GARDNER DR, GRUM D & MARCOLONGO-PEREIRA C. 2013. Production of the alkaloid swainsonine by a fungal endosymbiont of the Ascomycete order Chaetothyriales in the host Ipomoea carnea. J Agri Food Chem 61(16): 3797-3803. doi: 10.1021/jf4008423.), but no data are yet available regarding a specific fungal symbiont in this Argentine SW-containing species.

Ipomoea hieronymi (Kuntze) subsp. calchaquina (Family: Convolvulaceae; Figure 2b) is a creeping perennial plant with tuberous roots with branched and furrowed stems. Leaves are densely covered with short, soft light-gray hairs. Flowers are pink, with reddish-black seeds (Orfila et al. 1995ORFILA EN, D’ALFONSO C & NOVARA L. 1995. Convolvulaceae. Aportes Bot Salta Ser Flora 3(6): 1-87.). In Argentina, Ipomoea hieronymi is an autochthonous species that grows in the arid mountains of the northwest, in provinces like Catamarca, Tucumán, La Rioja, Salta and Jujuy, in lands between 1000 and 2000 m of elevation (Figure 2b). This area corresponds to the “Montes de Sierras y Bolsones” ecoregion, which is characterized by a dry and hot climate, with annual rainfall of 150-170 mm and temperatures ranging between 20 and 33°C in summer and between 8°C and 20°C in winter (Figure 3). Ipomoea hieronymi, locally called “Mechoacan” or “Mensuaca”, grows in areas where extensive livestock is composed mainly of goats and sheep bred for the farmers’ consumption and local commercialization (Bravo et al. 1999BRAVO G, BIANCHI A, VOLANTE J, ALDERETE SALAS S, SEMPRONII G, VICINI L & PICCOLO A. 1999. Regiones Agro-económicas del Noroeste Argentino. Paper presented at the meeting of the First Conferences of SIG. INTA-UNSE, Santiago del Estero, Argentina.).

Figure 2b
Distribution of Ipomoea hieronymi subsp. calchaquina in Argentina.

This plant was found to be toxic for the first time in a spontaneous outbreak in goats in Catamarca province. A plant sample taken from this province and toxicologically analyzed showed a SW concentration of 0.036 % (Table I) (Micheloud JF., unpublished data).

Astragalus garbancillo (Cav.) (Family: Fabaceae; Figure 2c) is 20 to 50 cm high, has odd-pinnate leaves and white to pale-violet flowers. The fruits contain 1-2 seeds (Gómez-Sosa 2004GÓMEZ-SOSA E. 2004. Species of the South American Astragalus garbancillo (Leguminosae-Papilionoideae) complex. Arnaldoa 11(2): 43-66.). It grows in the Andean region of Perú, Bolivia and Argentina. In Argentina, it grows in arid zones of the northwest and Cuyo, including Catamarca, Jujuy, La Rioja, Mendoza, Salta, San Juan, and Tucumán provinces, in lands between 1600 and 4500 m of elevation (Figure 2c) (Gómez-Sosa 1999GÓMEZ-SOSA E. 1999. Proposal to conserve the name Astragalus garbancillo (Leguminosae). Taxon 48(3): 593-594.). This area corresponds to the “Puna” ecoregion, which is characterized by a dry cold climate with large daily temperature variations, reaching minimum temperatures below –15 ºC (Figure 3) (Reboratti 2005REBORATTI C. 2005. Situación ambiental en las ecorregiones Puna y Altos Andes. In La Situación Ambiental de Argentina, p. 33-39. Http://www.fvsa.org.ar/situacionambiental/Puna.pdf (accessed on November 4, 2015).
Http://www.fvsa.org.ar/situacionambienta... ). In this region, goats, sheep, and South American camelids have a main impact on the economic life of rural families (Bravo et al. 1999BRAVO G, BIANCHI A, VOLANTE J, ALDERETE SALAS S, SEMPRONII G, VICINI L & PICCOLO A. 1999. Regiones Agro-económicas del Noroeste Argentino. Paper presented at the meeting of the First Conferences of SIG. INTA-UNSE, Santiago del Estero, Argentina.).

Figure 2c
Distribution of Astragalus garbancillo in Argentina.

Smallholders from Salta province have historically recognized A. garbancillo as a plant toxic to sheep, goats, cattle and mules in the spring-summer season (Califano & Echazu 2013CALIFANO LM & ECHAZU F. 2013. Etnobotánica en comunidades pastoriles. Conocimiento tradicional sobre especies tóxicas para el ganado en la cuenca del río Iruya (Salta, Argentina). Soc Arg Bot 48: 365-375. doi:10.31055/1851. 2372.v48. n2.6271.). A. garbancillo var. garbancillo has been recently deposited in the Herbarium of the National University of Salta and the SW concentration from composite samples at early vegetative stage was found to be 0.03% (Table I) (Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.).

Astragalus pehuenches (Nierdel) (Family: Fabaceae; Figure 2d) is a legume that varies from 10 to 45 cm in height. The leaves are 5 to 9 cm long and the plant has purple/blue flowers. The fruits have a glabrous capsule that can contain 12-14 black seeds (Gómez-Sosa 1979GÓMEZ-SOSA E. 1979. Las especies sudamericanas del género Astragalus (Leguminosae). Las especies patagónicas argentinas. Darwiniana 313-376.). It is distributed throughout Andean and extra Andean areas of Argentine Patagonia, and grows spontaneously in Mendoza, Neuquén, Río Negro and Chubut provinces in lands between 900 and 1200 m of elevation (Figure 2d). This area corresponds to the “Estepa Patagónica” ecoregion, which is characterized by a semiarid climate, with an annual average rainfall of 200 mm and temperatures ranging between 9°C and 25°C in summer and between -2°C and 7°C in winter (Figure 3). In general, the landscapes are composed of large steppes covered by shrubs and perennial grasses and small meadows covered by annual and perennial grasses (Bran et al. 2000BRAN D, AYESA J & LOPEZ C. 2000. Regiones Ecológicas de Río Negro. Comunicación técnica, 59 p.). Astragalus pehuenches, locally called “Garbancillo” or “Yerba loca”, sometimes forms patches following the runoff of rainwater and winds (Gómez-Sosa 1979GÓMEZ-SOSA E. 1979. Las especies sudamericanas del género Astragalus (Leguminosae). Las especies patagónicas argentinas. Darwiniana 313-376.). In the areas where A. pehuenches grows, there are approximately 1.35 million Merino sheep, 0.54 million Angora and Creole goats, and 0.37 million Hereford cattle (SENASA 2018SENASA-SERVICIO NACIONAL DE SANIDAD Y CALIDAD AGROALIMENTARIA 2018. Anuario Estadístico 2017 – Centro Regional Patagonia Norte, Argentina. http://www.casadelletres.eu/redaccion_cientifica_registro.html/.
http://www.casadelletres.eu/redaccion_ci... ). Livestock is generally bred as mixed flocks composed mainly of sheep and goats and sometimes cattle in open fields managed by smallholders with scarce or null technology (Easdale & Rosso 2010EASDALE MH & ROSSO H. 2010. Dealing with drought: social implications of different smallholder survival strategies in semi-arid rangelands of Northern Patagonia, Argentina. The Rang J 32(2): 247-255. doi:10.1071/RJ09071.).

Figure 2d
Distribution of Astragalus pehuenches in Argentina.

Astragalus pehuenches has been mentioned as a poisonous plant in the region since 1830 (Kauffer & Heinken 1984KAUFFER C & HEINKEN R. 1984. Informe sobre mortandad de equinos en el Dpto. Gastre por intoxicación con Astragalus spp. Dirección de Ganadería de la provincia de Chubut. Secretaría de Asuntos Agrarios: Argentina, 8 p.). In 1991, SW was identified on two herbarium specimens from Mendoza and Chubut provinces (Molyneux & Gomez-Sosa 1991MOLYNEUX RJ & GOMEZ-SOSA E. 1991. Presencia del alcaloide indolizidínico Swainsonine en Astragalus pehuenches (Leguminosae galegueae). Soc Arg Bot 27: 59-64.). High concentrations of SW from 0.070 to 0.097% were determined in this region (Table I) (Martinez et al. 2018MARTINEZ A, GARDNER D, COOK D, GIMENO EJ & ROBLES CA. 2018. Potencial toxigénico de Astragalus pehuenches Niederl en Argentina. RIA 44(3): 378-383.). Recently, a SW-producing endophyte from this species has been detected and demonstrated to belong to the genus Alternaria section Undifilum by culture and molecular analysis (Martinez et al. 2019bMARTINEZ A, ROBLES C, ROPER J, GARDNER DR, NEYAZ MS, JOELSON NZ & COOK D. 2019b. Detection of swainsonine-producing endophytes in Patagonian Astragalus species. Toxicon 171: 1-6. doi.org/10.1016/j.toxicon.2019.09.020.).

Finally, Sida rodrigoi (Monteiro) (Family: Malvaceae; Figure 2e) is an evergreen shrub 0.50-1.50 m high, with glabrous stems and distichous leaves. The yellowish flowers have axillaries in groups of two, and the fruits have glabrous seeds. It is found in subtropical areas, in eastern Bolivia, Paraguay and northern and northeastern Argentina, including the provinces of Chaco, Corrientes, Formosa, Jujuy and Salta, in lands between 70 and 1600 m of elevation (Figure 2e) (Krapovickas 2003KRAPOVICKAS A. 2003. Sida sección distichifolia (Monteiro) Krapov. comb. nov., stat. nov.(Malvaceae-Malveae). Bonplandia 83-121.). The area corresponds to the northern area of the “Chaco Seco” ecoregion, which has subtropical warmth (Figure 3). Sida rodrigoi, locally called “Afata”, grows in edges of the jungle in gallery, roads and non-productive lands. In this region, the most important economic activity is extensive animal production, with goats and cattle being the predominant animals bred in farms (Bravo et al. 1999BRAVO G, BIANCHI A, VOLANTE J, ALDERETE SALAS S, SEMPRONII G, VICINI L & PICCOLO A. 1999. Regiones Agro-económicas del Noroeste Argentino. Paper presented at the meeting of the First Conferences of SIG. INTA-UNSE, Santiago del Estero, Argentina.).

Figure 2e
Distribution of Sida rodrigoi in Argentina.

In 2017, S. rodrigoi was reported for the first time as a toxic plant in Jujuy province. Plant samples were deposited in the Herbarium of the National University of Salta province and toxicological analysis determined a SW concentration of 0.033% (Table I) (Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.).

Figure 3
Different Ecoregions of Argentina.

RESULTS AND DISCUSSION

Spontaneous and experimental poisoning

Stegelmeier et al. (2007)STEGELMEIER BL, LEE ST, JAMES LF, GARDNER DR, PANTER KE, RALPHS MH & PFISTER JA. 2007. The comparative pathology of locoweed poisoning in livestock, wildlife and rodents. In: Panter, Kip, Wierenga TL and Pfister JA. (Eds). Poisonous Plants. Global Research and Solutions. Cabi Publishing, Wallingford: UK, p. 359-365. and Lu et al. (2013)LU H, WANG SS, ZHOU QW, ZHAO YN & ZHAO BY. 2013. Damage and control of major poisonous plants in the western grasslands of China–a review. The Rang J 34(4): 329-339. doi: 10.1071/RJ12057. reported that the animals most sensitive to SW toxicity are horses. Although no cases of intoxication in this animal species have been reported in Argentina, a few cases of horses with behavioral changes, loss of equilibrium, ataxia and death, which had been grazing on A. pehuenches, have been observed in Patagonia (Robles C., unpublished data).

In Argentina, spontaneous poisoning by Ipomoea carnea, Ipomoea hieronymi and Sida rodrigoi has been reported in goats (Rodriguez Armesto et al. 2004RODRIGUEZ ARMESTO RR, REPETTO AE, ORTEGA HH, PERALTA CJ, PENSIERO JF & SALVETTI N. 2004. Intoxicación en cabras por ingestión de Ipomoea hieronymi var. Calchaquina en la provincia de Catamarca, Argentina. Rev Vet Arg 21: 332-341., Ríos et al. 2015RÍOS EE, CHOLICH LA, CHILESKI G, GARCÍA EN, LÉRTORA J, GIMENO EJ & TEIBLER GP. 2015. Suspected natural lysosomal storage disease from ingestion of pink morning glory (Ipomoea carnea) in goats in northern Argentina. J Vet Med Sci 77(7): 847-850. doi: 10.1292/jvms.14-0317. https://doi.org/10.1292/jvms.14-0317., Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.), spontaneous poisoning by Astragalus garbancillo and Astragalus pehuenches has been reported in sheep (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.) and spontaneous poisoning by A. pehuenches has been reported in cattle (Martinez et al. 2019aMARTINEZ A, LAUROUA C, BORRELLI LB, GARDNER DR & ROBLES CA. 2019a. Spontaneous outbreak of Astragalus pehuenches (Fabaceae) poisoning in cattle in Argentina. Toxicon 157: 84-86. https://doi.org/10.1016/j.toxicon.2018.11.303.).

In the outbreak by S. rodrigoi in goats in 2017, the epidemiological rates of morbidity and lethality were 81% (160/196) and 51% (100/196), respectively. The main predisposing factors were the high animal load (24.8 animals/ha), evidence of overgrazing, and low-forage availability (Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.).

In the spontaneous poisoning by A. pehuenches, the mortality rate was 90% (63/70) in cattle (Martinez et al. 2019aMARTINEZ A, LAUROUA C, BORRELLI LB, GARDNER DR & ROBLES CA. 2019a. Spontaneous outbreak of Astragalus pehuenches (Fabaceae) poisoning in cattle in Argentina. Toxicon 157: 84-86. https://doi.org/10.1016/j.toxicon.2018.11.303.) and 73% (273/300) in sheep (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384.). In the last case, the intoxication occurred in winter, although the snow had covered the available grass (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384.). When outbreaks of intoxication in cattle by A. pehuenches were seen in late summer, the herd was grazing on a pasture of approximately 2700 hectares, with clear signs of overgrazing (Martinez et al. 2019aMARTINEZ A, LAUROUA C, BORRELLI LB, GARDNER DR & ROBLES CA. 2019a. Spontaneous outbreak of Astragalus pehuenches (Fabaceae) poisoning in cattle in Argentina. Toxicon 157: 84-86. https://doi.org/10.1016/j.toxicon.2018.11.303.).

Regarding A. garbancillo, farmers have reported that between 0.5 and 2% of the flocks are affected every year, and that the problem is more severe in dry years, with cases usually occurring between August and December. Due to poor information from farmers, both the morbidity and lethality rates of the poisoning by A. garbancillo and Ipomoea sp. have not yet been possible to calculate (Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.).

Some studies on experimental poisoning by some of these plants have been performed. For example, experimental poisoning by I. carnea was studied in goats, in which the intake of I. carnea was 50 g per kg of body weight per day and the intoxication occurred between 43 and 60 days in autumn (Ríos et al. 2008RÍOS E, CHOLICH LA, SILVA J & ACOSTA DE PÉREZ O. 2008. Histopathological Lesions on central nervous system intoxication of goats by Ipomoea carnea spp fistulosa (Convolvulácea). Rev Vet 19(2): 130-134.). In spring, this value was reduced to 21 days (Ríos et al. 2012RÍOS EE, CHOLICH LA, GIMENO EJ, GUIDI MG & ACOSTA DE PÉREZ OC. 2012. Experimental poisoning of goats by Ipomoea carnea subsp. fistulosa in Argentina: a clinic and pathological correlation with special consideration on the central nervous system. Pesq Vet Bras 32(1): 37-42. http://dx.doi.org/10.1590/S0100-736X2012000100007.). Armién et al. (2007)ARMIÉN AG, TOKARNIA CH, PEIXOTO PV & FRESE K. 2007. Spontaneous and experimental glycoprotein storage disease of goats induced by Ipomoea carnea subsp fistulosa (Convolvulaceae). Vet Pathol 44(2): 10-184. doi:10.1354/vp.44-2-170. reported that poisoning by I. carnea occurred after the administration of doses between 23 and 96 g of green plant material per kg of body weight per day, for a 21–105-day trial. However, these values are difficult to compare because these studies did not report the amount of SW present in the plants.

In addition, in a previous study of our group, experimental poisoning by A. pehuenches was studied in sheep, in which a daily dose of 2 mg SW per kg of body weight was used (Martínez et al. 2016). In this study, the SW analysis was performed on the ground plant, resulting in 0.097 % SW. Then, the intake necessary to reach the proposed dose was calculated and the disease was reproduced in 54 days (Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p.). To our knowledge, this study with A. pehuenches was the first with a dose of SW previously analyzed on the ground plant.

Clinical signs produced by poisoning with SW-containing plants

Animals poisoned by SW-containing plants exhibit weight loss and related nervous clinical signs, characterized by tremors of head and neck, abnormalities of gait, difficulty in standing, ataxia and wide-based stance (Figure 4a) (Rodríguez Armesto et al. 2004, Ríos et al. 2015RÍOS EE, CHOLICH LA, CHILESKI G, GARCÍA EN, LÉRTORA J, GIMENO EJ & TEIBLER GP. 2015. Suspected natural lysosomal storage disease from ingestion of pink morning glory (Ipomoea carnea) in goats in northern Argentina. J Vet Med Sci 77(7): 847-850. doi: 10.1292/jvms.14-0317. https://doi.org/10.1292/jvms.14-0317., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.,b, Martinez et al. 2019aMARTINEZ A, LAUROUA C, BORRELLI LB, GARDNER DR & ROBLES CA. 2019a. Spontaneous outbreak of Astragalus pehuenches (Fabaceae) poisoning in cattle in Argentina. Toxicon 157: 84-86. https://doi.org/10.1016/j.toxicon.2018.11.303.). In particular sheep poisoned by A. garbancillo show abnormal posture similar to a dog’s sitting position (Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.), and goats poisoned by I. carnea and S. rodrigoi show paresis of the hind legs (Ríos et al. 2015RÍOS EE, CHOLICH LA, CHILESKI G, GARCÍA EN, LÉRTORA J, GIMENO EJ & TEIBLER GP. 2015. Suspected natural lysosomal storage disease from ingestion of pink morning glory (Ipomoea carnea) in goats in northern Argentina. J Vet Med Sci 77(7): 847-850. doi: 10.1292/jvms.14-0317. https://doi.org/10.1292/jvms.14-0317., Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.). When the animals are disturbed, these signs are exacerbated and the animals tend to lose the equilibrium (Rodríguez Armesto et al. 2004, Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011., b, Martinez et al. 2019aMARTINEZ A, LAUROUA C, BORRELLI LB, GARDNER DR & ROBLES CA. 2019a. Spontaneous outbreak of Astragalus pehuenches (Fabaceae) poisoning in cattle in Argentina. Toxicon 157: 84-86. https://doi.org/10.1016/j.toxicon.2018.11.303.).

Figure 4
a. Clinical signs. Spontaneous poisoning of a goat by Sida rodrigoi. The goat shows abnormal posture due to difficulty in standing. b. Histology. Spontaneous poisoning of sheep by Astragalus garbancillo. Cerebellar basal nuclei show severe cytoplasmic vacuolation. HE, bar 25 μm. c. Lectin histochemistry. Spontaneous poisoning of a goat by Sida rodrigoi. Lectin WGA labeled the perikaryon of Purkinje cells in goats. Lectin histochemistry, bar 25 μm. d. Transmission electron microscopy (TEM). Experimental poisoning of sheep by Astragalus pehuenches. Purkinje cell showing numerous membrane-bound cytoplasmic vacuoles (V) measuring 1 to 10 μm in diameter. These vacuoles rarely contain membrane fragments.

Experimental toxicity with a single Ipomoea sp. has been found to produce anemia in goats (Ríos et al. 2005RÍOS E, BELMONTE C, RODRIGUEZ C, ORTIZ L, CIOTTI EM, BOGADO F & ACOSTA DE PÉREZ OA. 2005. Intoxicación con Ipomoea fistulosa (aguapeí, mandiyurá) en cabras. Efectos sobre el hemograma e ionograma. Rev Vet 16(1): 21-24.). Likewise, pronounced anemia has been observed in sheep that ingested Astragalus lentiginosus (Stegelmeier et al. 1995aSTEGELMEIER BL, JAMES LF, PANTER KE & MOLYNEUX RJ. 1995a. Serum swainsonine concentration and alpha-mannosidase activity in cattle and sheep ingesting Oxytropis sericea and Astragalus lentiginosus (locoweeds). Am J Vet Res 56: 149-154.) and I. carnea (Adam et al. 1973ADAM SEI, TARTOUR G, OBEID HM & IDRIS OF. 1973. Effects of Ipomoea carnea on the liver and on serum enzymes in young ruminants. J Comp Pathol 83(4): 531-542. doi:10.1016/0021-9975(73)90011-x., Schumaher-Henrique et al. 2003SCHUMAHER HENRIQUE B, GORNIAK SL, DAGLI MLZ & SPINOSA HS. 2003. The clinical, biochemical, haematological and pathological effects of long-term administration of Ipomoea carnea to growing goats. Vet Res Comm 27(4): 311-319.).

Goats intoxicated by S. rodrigoi in the field also showed abortions and stillbirths (Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.). Finally, animals intoxicated with I. carnea (Armién et al. 2011ARMIÉN AG, TOKARNIA CH, PEIXOTO PV, BARBOSA JD & FRESE K. 2011. Clinical and morphologic changes in ewes and fetuses poisoned by Ipomoea carnea subspecies fistulosa. J Vet Diagn Invest 23(2): 221-232. doi:10.1177/104063871102300205.), locoweed (Astragalus and Oxytropis) (Stegelmeier et al. 1999STEGELMEIER BL, JAMES LF, PANTER KE, GARDNER DR, PFISTER JA, RALPHS MH & MOLYNEUX RJ. 1999. Dose response of sheep poisoned with locoweed (Oxytropis sericea). J Vet Diagn Inv 11(5): 448-456. doi:10.1177/104063879901100510.) and Sida carpinifolia (Pedroso et al. 2012PEDROSO PM, COLODEL EM, SEITZ AL, CORREA GL, SOARES MP & DRIEMEIER D. 2012. Pathological findings in fetuses of goats and cattle poisoned by Sida carpinifolia (Malvaceae). Pesq Vet Bras 32(3): 227-230. http://dx.doi.org/10.1590/S0100-736X2012000300008.) from other locations have also shown other reproductive disorders, including altered libido, infertility and fetal malformations.

Histological lesions and diagnosis

The typical histological lesion found in animals poisoned by ingestion of SW-containing plants is the cytoplasmic vacuolation of many cell types, including neurons, especially Purkinje cells of the cerebellum. Many of the remaining cells exhibit necrosis with pyknotic and condensed cytoplasm (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384., Rodriguez Armesto et al. 2004RODRIGUEZ ARMESTO RR, REPETTO AE, ORTEGA HH, PERALTA CJ, PENSIERO JF & SALVETTI N. 2004. Intoxicación en cabras por ingestión de Ipomoea hieronymi var. Calchaquina en la provincia de Catamarca, Argentina. Rev Vet Arg 21: 332-341., Ríos et al. 2012RÍOS EE, CHOLICH LA, GIMENO EJ, GUIDI MG & ACOSTA DE PÉREZ OC. 2012. Experimental poisoning of goats by Ipomoea carnea subsp. fistulosa in Argentina: a clinic and pathological correlation with special consideration on the central nervous system. Pesq Vet Bras 32(1): 37-42. http://dx.doi.org/10.1590/S0100-736X2012000100007., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011., b, Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p., 2019a). Animals poisoned with Sida rodrigoi and Astragalus pehuenches have also been found to present axonal swelling, axonal torpedoes and astrocytosis at the cerebellar cortex and medulla oblongata (Figure 4b) (Robles et al. 2000ROBLES CA, SABER C & JEFFREY M. 2000. Astragalus pehuenches (Locoweed) poisoning in a Merino sheep flock in the Patagonia region, Argentina. Rev Med Vet 81(5): 380-384., Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p., 2019a, Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.).

Vacuolation is also extended to other tissues, such as hepatocytes and Kupffer cells, renal tubular epithelia, uroepithelial cells and exocrine pancreatic cells (Rodriguez Armesto et al. 2004RODRIGUEZ ARMESTO RR, REPETTO AE, ORTEGA HH, PERALTA CJ, PENSIERO JF & SALVETTI N. 2004. Intoxicación en cabras por ingestión de Ipomoea hieronymi var. Calchaquina en la provincia de Catamarca, Argentina. Rev Vet Arg 21: 332-341., Ríos et al. 2005RÍOS E, BELMONTE C, RODRIGUEZ C, ORTIZ L, CIOTTI EM, BOGADO F & ACOSTA DE PÉREZ OA. 2005. Intoxicación con Ipomoea fistulosa (aguapeí, mandiyurá) en cabras. Efectos sobre el hemograma e ionograma. Rev Vet 16(1): 21-24., 2009RÍOS E, CHOLICH L, TEIBLER G, BOGADO F & MUSSART N. 2009. Lesiones renales y pancreáticas inducidas por Ipomoea carnea en cabras. Rev Vet 20(1): 45-49., Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011., b). Lesions in the thyroid follicular epithelia (Micheloud et al. 2017bMICHELOUD JF, MARIN R, MARTINEZ A, MARTINEZ OG, GARDNER DR & GIMENO EJ. 2017a. Poisoning by Astragalus garbancillo var. garbancillo in sheep in Northwestern Argentina. Intern J Pois Plant Res 4: 72-78.), myocardium (Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011.) and uterus (Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p.) have also been observed in goats and sheep poisoned by Sida and Astragalus sp.

In experimental poisoning with Astragalus pehuenches in sheep, immunohistochemistry has revealed that astrocytes from white matter, the molecular layer and the Purkinje cells surrounding it express higher levels of the glial fibrillary acidic protein (GFAP) (Martinez 2015MARTINEZ A. 2015. Intoxicación por Astragalus pehuenches: caracterización clínica, bioquímica e histopatológica en cobayos y ovinos. Dissertation, University of La Plata, Buenos Aires: Argentina, 121 p.). In addition, analysis of the expression of Ionized calcium-binding adaptor molecule 1(Iba-1) has allowed detecting foci of microgliosis of the molecular layer (Martinez 2015MARTINEZ A. 2015. Intoxicación por Astragalus pehuenches: caracterización clínica, bioquímica e histopatológica en cobayos y ovinos. Dissertation, University of La Plata, Buenos Aires: Argentina, 121 p.). Lectin histochemistry is a useful technique to identify the presence of specific carbohydrate residues inside cells in situ. According to Alroy et al. (1985)ALROY J, ORGAD U, UCCI AA & GAVRIS VE. 1985. Swainsonine toxicosis mimics lectin histochemistry of mannosidosis. Vet Pathol 22(4): 311-316. doi:10.1177/030098588502200403., in cells affected by Astragalus and Swainsona toxicosis, Concanavalia ensformis agglutinin (CON-A), Wheat Germ Agglutinin (WGA) and Succinyl Wheat Germ Agglutinin (S-WGA) specifically bind to a-mannosyl residues and β-N-acetyl glucosamine. The tissues from animals poisoned by the three plant genera reported in Argentina have been found to show significant affinity to the lectin Lens culinary (LCA) and to the a-mannosyl residues detected with CON-A, WGA and S-WGA (Figure 4c) (Ríos et al. 2012RÍOS EE, CHOLICH LA, GIMENO EJ, GUIDI MG & ACOSTA DE PÉREZ OC. 2012. Experimental poisoning of goats by Ipomoea carnea subsp. fistulosa in Argentina: a clinic and pathological correlation with special consideration on the central nervous system. Pesq Vet Bras 32(1): 37-42. http://dx.doi.org/10.1590/S0100-736X2012000100007., 2015, Martinez et al. 2016MARTINEZ A, GARDNER D & ROBLES CA. 2016. Intoxicación experimental por Astragalus pehuenches: caracterización histopatológica en ovinos. Premio “Osvaldo Eckell” de la Academia Nacional de Agronomía y Veterinaria. Anales de la ANAV, 32 p., Micheloud et al. 2017aMICHELOUD JF, MARIN R, COLQUE-CARO LA, MARTÍNEZ OG, GARDNER D & GIMENO EJ. 2017b. Swainsonine-induced lysosomal storage disease in goats caused by the ingestion of Sida rodrigoi Monteiro in North-western Argentina. Toxicon 128: 1-4. doi: 10.1016/j.toxicon.2016.12.011., b). This histochemistry staining pattern of the vacuoles indicates that they contain N-glycosidically bound oligosaccharides. These results are similar to those reported previously for animals poisoned by ingestion of SW-containing plants (Driemeier et al. 2000DRIEMEIER D, COLODEL EM, GIMENO EJ & BARROS SS. 2000. Lysosomal storage disease caused by Sida carpinifolia poisoning in goats. Vet Path 37: 153-159. doi: 10.1354/vp.37-2-153., Loretti et al. 2003LORETTI AP, COLODEL EM, GIMENO EJ & DRIEMEIER D. 2003. Lysosomal storage disease in Sida carpinifolia toxicosis: an induced mannosidosis in horses. Eq Vet J 35: 434-438. doi:10.2746/042516403775600523., Seitz et al. 2005SEITZ AL, COLODEL EM, SCHMITZ M, GIMENO EJ & DRIEMEIER D. 2005. Use of lectin histochemistry to diagnose Sida carpinifolia (Malvaceae) poisoning in sheep. Vet Rec 156(12): 386-388., Barbosa et al. 2006BARBOSA RC, RIET-CORREA F, MEDEIROS RMT, LIMA EF, BARROS SS, GIMENO EJ & GARDNER DR. 2006. Intoxication by Ipomoea sericophylla and Ipomoea riedelii in goats in the state of Paraíba, Northeastern Brazil. Toxicon 47: 371-379. doi: 10.1016/j.toxicon.2005.11.010., Armién et al. 2007ARMIÉN AG, TOKARNIA CH, PEIXOTO PV & FRESE K. 2007. Spontaneous and experimental glycoprotein storage disease of goats induced by Ipomoea carnea subsp fistulosa (Convolvulaceae). Vet Pathol 44(2): 10-184. doi:10.1354/vp.44-2-170., Mendonça et al. 2018MENDONÇA FS, SILVA FILHO GB, CHAVES HA, AIRES LD, BRAGA TC, GARDNER DR & BURIL MT. 2018. Detection of swainsonine and calystegines in Convolvulaceae species from the semiarid region of Pernambuco. Pesq Vet Bras 38(11): 2044-2051.).

Ultrastructurally, in spontaneous I. carnea poisoning, cytoplasmic vacuolation is evident in neurons and astrocytes of the thalamus and Purkinje cells, most of which are optically empty and delimited by a membrane (Ríos et al. 2012RÍOS EE, CHOLICH LA, GIMENO EJ, GUIDI MG & ACOSTA DE PÉREZ OC. 2012. Experimental poisoning of goats by Ipomoea carnea subsp. fistulosa in Argentina: a clinic and pathological correlation with special consideration on the central nervous system. Pesq Vet Bras 32(1): 37-42. http://dx.doi.org/10.1590/S0100-736X2012000100007.). Membrane fragments, reticular or dense granules and amorphous substances are also observed in some vacuoles (Ríos et al. 2012RÍOS EE, CHOLICH LA, GIMENO EJ, GUIDI MG & ACOSTA DE PÉREZ OC. 2012. Experimental poisoning of goats by Ipomoea carnea subsp. fistulosa in Argentina: a clinic and pathological correlation with special consideration on the central nervous system. Pesq Vet Bras 32(1): 37-42. http://dx.doi.org/10.1590/S0100-736X2012000100007.). This seems to be in accordance with the experimental intoxication by A. pehuenches, in which the vacuoles measured up to 10 μm in diameter (Figure 4d) (Martinez 2015MARTINEZ A. 2015. Intoxicación por Astragalus pehuenches: caracterización clínica, bioquímica e histopatológica en cobayos y ovinos. Dissertation, University of La Plata, Buenos Aires: Argentina, 121 p.).

An additional technique of diagnostic value, based on the use of liver biopsies, has been reported in poisoning by Ipomoea marcellia from Brazil (Rocha et al. 2016ROCHA BP, REIS MO, DRIEMEIER D, COOK D, CAMARGO LM, RIET-CORREA F & MENDONÇA FS. 2016. Biópsia hepática como método diagnóstico para intoxicação por plantas que contém swainsonina. Pesq Vet Bras 36(1): 373-377.). On the other hand, in Argentina, another method, based on the use of peripheral blood smears, has revealed vacuolation of lymphocytes from the 5th day of intoxication by I. carnea (García et al. 2015GARCÍA EN, AGUIRRE MV, GIMENO EJ, RIOS EE, ACOSTA OC & CHOLICH LA. 2015. Haematologic alterations caused by Ipomoea carnea in experimental poisoning of guinea pig. Exp Tox Path 67(10): 483-490. doi: 10.1016/j.etp.2015.07.002.). Both methods have been shown to be useful and should thus be used in the diagnosis of poisoning by SW-containing plants.

Diagnoses are made using epidemiological data. When making a diagnosis, the suspect plant should be confirmed to be the cause, and then differentiated from other causes of nervous diseases. Other nervous infectious diseases, including genetic α-mannosidosis, rabies, encephalitis by BoHV type 5, listeriosis and any disease that has been identified in livestock in Argentina, will depend on the ecoregion.

Currently, no treatment for the poisoning by SW-containing plants is available. In Argentina, the only way recommended to prevent intoxication is to keep livestock from consuming these toxic plants.

Animal models for the study of α-mannosidosis and other lysosomal storage diseases

Different animal models have been used to study the experimental poisoning by SW-containing plants. In Argentina, guinea pigs have been used to study the experimental reproduction of I. carnea intoxication (Cholich et al. 2009CHOLICH LA, GIMENO EJ, TEIBLER PG, JORGE NL & ACOSTA DE PÉREZ OC. 2009. The guinea pig as an animal model for Ipomoea carnea induced a-mannosidosis. Toxicon 54: 276-282. doi: 10.1016/j.toxicon.2009.04.012., García et al. 2015GARCÍA EN, AGUIRRE MV, GIMENO EJ, RIOS EE, ACOSTA OC & CHOLICH LA. 2015. Haematologic alterations caused by Ipomoea carnea in experimental poisoning of guinea pig. Exp Tox Path 67(10): 483-490. doi: 10.1016/j.etp.2015.07.002.), as well as to study experimental poisoning by A. pehuenches (Martinez 2015MARTINEZ A. 2015. Intoxicación por Astragalus pehuenches: caracterización clínica, bioquímica e histopatológica en cobayos y ovinos. Dissertation, University of La Plata, Buenos Aires: Argentina, 121 p.), A. garbancillo (Aban et al. 2016ABAN S, MICHELOUD JF, CHOLICH L & GIMENO EJ. 2016. Intoxicación experimental con Astragalus garbancillo (variedad garbancillo) en cobayos. Rev Med Vet 97(3): 19-20.) and Sida rodrigoi (Colque Caro et al. 2016COLQUE CARO LA, MICHELOUD JF & GIMENO EJ. 2016. Intoxicación experimental con Sida rodrigoi monteiro (kravop) en cobayos. Rev Med Vet 97: 15.). Swainsona galegifolia poisoning in guinea pigs was reported for the first time in Australia (Huxtable 1969HUXTABLE CR. 1969. Experimental reproduction and histopathology of Swainsona galegifolia poisoning in the guinea-pig. Aust J Exp Biol Med Sci 47: 339-347., Huxtable & Gibson 1970HUXTABLE CR & GIBSON A. 1970. Vacuolation of circulating lymphocytes in guinea-pigs and cattle ingesting Swainsona galegifolia. Aust Vet J 46(9): 446-448. https://doi.org/10.1111/j.1751-0813.1970.tb06685.x.). The advantages of this model are that histological changes in the central nervous system (CNS) are similar to those reported in poisoned livestock (Cholich et al. 2013CHOLICH LA, MÁRQUEZ M, BATLLE MP, GIMENO EJ, TEIBLER GP, RIOS EE & ACOSTA OC. 2013. Experimental intoxication of guinea pigs with Ipomoea carnea: Behavioural and neuropathological alterations. Toxicon 76: 28-36. doi:10.1016/j.toxicon.2013.08.062., Martinez 2015MARTINEZ A. 2015. Intoxicación por Astragalus pehuenches: caracterización clínica, bioquímica e histopatológica en cobayos y ovinos. Dissertation, University of La Plata, Buenos Aires: Argentina, 121 p.). Together with the neuronal vacuolation, one of the most important findings in the CNS of poisoned guinea pigs are spheroids, showing severe axonal dystrophy. These lesions play a key role in the diagnosis and pathogenesis of lysosomal storage diseases, including genetic and acquired α-mannosidosis (Jolly & Walkley 1997JOLLY RD & WALKLEY SU. 1997. Lysosomal storage diseases of animals: an essay in comparative pathology. Vet Path 34(6): 527-548. https://doi.org/10.1177/030098589703400601., Robinson et al. 2008ROBINSON AJ, CRAWLEY AC, AUCLAIR D, WESTON PF, HIRTE C, HEMSLEY KM & HOPWOOD JJ. 2008. Behavioural characterisation of the α-mannosidosis guinea pig. Beha Brain Res 186(2): 176-184. https://doi.org/10.1016/j.bbr.2007.08.005.).

Mice, rats and rabbits have also been used as models to study the effects of Astragalus sp. (Stegelmeier et al. 1995bSTEGELMEIER BL, MOLYNEUX RJ, ELBEIN AD & JAMES LF. 1995b. The Lesions of Locoweed (Astragalus mollissimus), Swainsonine, and Castanospermine in Rats. Vet Path 32(3): 289-298. doi:10.1177/030098589503200311.), Ipomoea carnea (Hueza et al. 2005HUEZA IM, GUERRA JL, HARAGUCHI M, ASANO N & GÓRNIAK SL. 2005. The role of alkaloids in Ipomoea carnea toxicosis: a study in rats. Exp Tox Path 57(1): 53-58. doi:10.1016/j.etp.2005.02.004.), and Oxytropis sp. (Li et al. 2012LI QF, HAO CJ, XU YP, LIANG J, YANG K & CUI ZH. 2012. Identification of a new locoweed (Oxytropis serioopetala) and its clinical and pathological features in poisoned rabbits. J Vet Med Sci 74(8): 989-993. doi: 10.1292/jvms.11-0557.). Nevertheless, these animals are not good models of research because rats present no neuronal lesions (Hueza et al. 2005HUEZA IM, GUERRA JL, HARAGUCHI M, ASANO N & GÓRNIAK SL. 2005. The role of alkaloids in Ipomoea carnea toxicosis: a study in rats. Exp Tox Path 57(1): 53-58. doi:10.1016/j.etp.2005.02.004.), and mice present lesions only with very high doses of SW, and do not develop extensive neuronal vacuolations, with subsequent axonal dystrophy (Stegelmeier et al. 1995b, 2008). Finally, rabbits poisoned with Oxytropis sp. show severe microvacuolation of the cerebrum and cerebellum, but no other lesions (Li et al. 2012LI QF, HAO CJ, XU YP, LIANG J, YANG K & CUI ZH. 2012. Identification of a new locoweed (Oxytropis serioopetala) and its clinical and pathological features in poisoned rabbits. J Vet Med Sci 74(8): 989-993. doi: 10.1292/jvms.11-0557.). Thus, the guinea pig model retains a number of advantages compared to traditional species as rats, mice and rabbits, including the fact that guinea pigs consume the toxic plants voluntarily and that it is a reproducible alternative (Cholich et al. 2009CHOLICH LA, GIMENO EJ, TEIBLER PG, JORGE NL & ACOSTA DE PÉREZ OC. 2009. The guinea pig as an animal model for Ipomoea carnea induced a-mannosidosis. Toxicon 54: 276-282. doi: 10.1016/j.toxicon.2009.04.012.).

CONCLUSION

Although Ipomoea carnea, I. hieronymi, Astragalus pehuenches, A. garbancillo and Sida rodrigoi grow in different ecoregions of Argentina, they all contain SW. Thus, these plants should be considered an important limiting factor for livestock breeding in Argentina, especially in fields managed by smallholders with scarce or null technology.

Considering the similarity between histological and ultrastructural alterations observed in ruminants and guinea pigs after experimental intoxication, guinea pig studies have allowed demonstrating that this animal model is sensitive to poisoning by plants containing SW.

It seems highly probable that a fungal symbiont is associated with Argentine SW-containing plant species, but this deserves further investigation.

ACKNOWLEDGMENTS

We thank Tech. Fernando Umaña from INTA Bariloche who edited the maps. Many of the studies reviewed in this work have been supported by grants from INTA (Regional Project 1281102 and National Project 1115054), FONCyT (PICT 1379-2011; 0900-2017), UNNE (PI: B001-2009 and PI: B009-13) and Consejo de Investigación de la Universidad Católica de Salta (Resol. 1494/16).

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