ABSTRACT
Cereus hildmannianus K. Schum is a columnar cactus native to South and Southeast Brazil. The cultivation of this species seems justifiable for several reasons: its fruits are spineless and edible; it is not threatened with extinction; it naturally occurs in Pampa and Atlantic Forest under non-xeric conditions that may be unsuitable for the cultivation of other tropical cacti; and the plants are pollinator-dependent and so should benefit from native pollinators. This study aimed to test seed germination of C. hildmannianus with samples collected at three different localities in southern Brazil, as a necessary step preceding any attempts of management and domestication. Seeds were exposed to temperatures of 20° C, 25° C, 30° C and room temperature. The germinability, average germination time and synchronization index were calculated. All samples showed higher germinability at 20° C and 25° C. Seeds from Caçapava do Sul and Santiago showed significant variation in the synchronization index at 25° C and 30° C, respectively. Seeds from Porto Alegre had maximum germinability, indicating greater vigor. Our results show that the seeds of C. hildmannianus germinate well and thrive within a wide range of temperatures and that cultivation of the species from seed-raised plants should not be problematic.
Keywords: cacti; Cereus hildmannianus; germinability; germination; synchronicity; tuna
Introduction
For centuries, Native Americans have exploited cacti as food, forage, a source of building materials and for medicinal purposes (Pimienta-Barrios & Nobel 1994). Whereas the cultivation and domestication of native cacti is particularly widespread in Mesoamerica (Casas & Barbera 2002), at least nine cactus species are used for diverse purposes in North-east Brazil (Lucena et al. 2013). The usefulness of these cacti has inspired attempts to introduce them into different semi-arid ecozones around the world (Mizrahi 2014). However, the economic potential of several other cacti (either Brazilian or not) has certainly been overlooked.
Cereus hildmannianus K. Schum., popularly known as “tuna”, is a species of columnar and arborescent cactus that occurs in Paraguay, South Brazil, Uruguay and the Argentinean Pampa grasslands (Taylor & Zappi 2004). The species is a potential crop, with its fruits being appreciated and used as food (Pesce 2011). In addition, its cladodes are used as a medicinal resource (Chavez & Zanin 2011). Mucilage of tuna has insecticidal properties, and can, for example, be used to control the larvae of Aedes aegypti (Culicidae) (Kamakshi et al. 2015). Nevertheless, tuna is scarcely mentioned in ethnobotanic studies, unlike other species of the same genus, such as Cereus albicaulis Britton & Rose (Chaves et al. 2015; Silva 2015), C. jamacaru DC. (Albuquerque et al. 2007; Lucena et al. 2013; Lucena et al. 2012; Santana et al. 2018) and C. repandus (L.) Mill. (Pasa et al. 2005; Carneiro et al. 2014; Mizrahi 2014; as Cereus peruvianus), which occur in Northeast Brazil. Many species of Cactaceae show high degrees of parallel evolution in vegetative, fruit and floral traits, which bring a convergence of uses (Barthlott & Hunt 1993). In other words, plants of C. hildmannianus could be as useful as the species cited above, and thus an important and useful resource for native human populations.
Tuna occurs throughout the state of Rio Grande do Sul, in its two biomes, the Pampa and Atlantic Forest, and in all its different environments, such as coastline, rainforest and grasslands (Carneiro et al. 2016). Two subspecies are recognized: Cereus hildmannianus subsp. hildmannianus, is restricted to the southern Brazil coastline and around the Lagoa dos Patos region; and Cereus hildmannianus subsp. uruguayanus, which occurs in western Rio Grande do Sul and Santa Catarina states and throughout the state of Paraná. Morphological differences can be observed in flower length; the flower of C. hildmannianus subsp. hildmannianus can reach over 20 cm long, while that of C. hildmannianus subsp. uruguayanus reaches up to 16 cm (Becker, in. prep.). The distinction of the two subspecies is supported by a recent phylogeographic study that evidenced a vicariance process, sorting out the populations of the two subspecies, probably due to environment changes during the Quaternary period (Silva et al. 2018). These lineages agree with the currently accepted subspecies (Carneiro et al. 2016) and, consequently, match the observed variability in floral tube length (Becker, in. prep.).
Cereus hildmannianus can reproduce by vegetative means or sexually through seeds produced via pollination. The latter enables genetic enhancement through the mixing of different variants and the selection of individuals with the most appreciated characteristics, such as productivity, fruit shape and climatic adaptations (Rech et al. 2014). Besides that, cacti have always been the subject of intensive exploitation due to their great ornamental value and, as a result, their populations have been drastically affected by overcollection and other anthropogenic perturbations such as mining and raising cattle (Rojás-Aréchiga & Vasquez-Yanes 2000). Currently, there are 68 species of cacti known for the state of Rio Grande do Sul (Flora do Brasil 2020 em Construção 2020), which represents about 30 % of Brazilian Cactaceae. Furthermore, 53 of these species are considered endangered according to IUCN guidelines (Carneiro et al. 2016). Propagation studies could constitute a contribution to the conservation of this natural resource because it promotes the possibility of obtaining valuable plants through controlled methods that could decrease the demand for illegal wild-collected material (Rojás-Aréchiga & Vasquez-Yanes 2000). Thus, studies involving reproduction and germination are needed in order to understand the best strategies for conservation-wise or economic-wise management, as for C. repandus, a fruit-crop marketed in Israel that first needed several studies regarding its ideal germination conditions (Ninio et al. 2003; Mizrahi 2014; as Cereus peruvianus).
An important factor in germplasm development is temperature, the understanding of which is essential for comprehending the ecophysiological and biochemical features by which species are adapted to the environment (Labouriau 1983; Ferreira & Borghetti 2004). Temperature rules germplasm capacity and breaks or induces dormancy (Bewley & Black 1994), in addition to affecting germination speed and synchronicity (Carvalho & Nakagawa 2000). These parameters are important for comparing germination of different seeds and measuring their respective performances.
The aims of this study, therefore, are to evaluate how temperature affects the germination of C. hildmannianus seeds collected from different localities, find the optimum temperature for germination and compare vigor among sampled populations. In our opinion, the cultivation and domestication of C. hildmannianus in South and Southeast Brazil could be justified for several reasons: (1) it is a native, widespread plant resource whose spineless fruits are edible and already known as such by nearby human populations; (2) it is not a threatened species (LC - Least Concern, according to Carneiro et al. 2016; according to IUCN guidelines); (3) it is widely distributed in two Biomes, the Pampa and Atlantic Forest, which is suggestive of high climatic tolerance; and (4) it is pollinator-dependent and relies on the agency of native insects to set fruit (Becker, in. prep.). Thus, from an environmental point of view, the cultivation of this native cactus could benefit from the services of native pollinators. Indeed, C. hildmannianus is native in areas with relatively high rainfall and low temperatures; such localities being probably unsuitable for cacti from the Caatinga (such as C. jamacaru) or from other tropical regions. Whereas very ripe fruits of C. hildmannianus may split under natural conditions (a fact that could complicate its commercialization), we think that this problem could be solved with appropriated harvesting practices of looking for populations whose fruits lack this feature. In fact, our field observations indicate that not all ripe fruits split (see Results), suggesting that more in-depth research is needed. The questions behind this contribution are: How is the germination of seeds of C. hildmannianus from different localities affected by temperature? Do seeds from different localities germinate similarly under the same temperatures or will they perform differently? Our hypothesis is that seeds from some localities may perform differently and, consequently, may be more interesting than others as a source of germplasm.
Materials and methods
We used Cereus hildmannianus seeds from fruits collected at the localities of Porto Alegre (30°14’10.3” S; 51°05’57.9” W), Santiago (29°29’57.3” S; 54°43’38.2” W) and Caçapava do Sul (30°39’04.9” S; 53°34’34.9” W), all in Rio Grande do Sul, Brazil) Table 1 summarizes the main climatic features of the collecting localities. Silva et al. (2018) showed, through molecular analyses, a vicariance process in the evolutionary history of C. hildmannianus populations of South Brazil. This process may have taken place after climate changes in the Quaternary period, originating two main clades. With this information as a framework, the three localities we chose for collecting fruits were also sampled in the study of Silva et al. (2018) and represent each haplotype and an intermediate population to guarantee genetic diversity for the germination tests. Thus, Porto Alegre represents the long-flowered lineage (subsp. hildmannianus), while Santiago represents the short-flowered lineage (subsp. uruguayanus). The phylogeographic study of Silva et al. (2018) considered Caçapava do Sul as an intermediate population, yet clearly bearing morphological features of subsp. hildmannianus. The use of seeds from different populations encompassing the two currently accepted subspecies allows a systematic comparison of their germination features. Since the present contribution is biased towards the domestication and management of C. hildmannianus, testing seeds from different localities or varieties is a powerful tool for discovering valuable germplasm.
Five fruits were collected from each locality in March and April 2019. The fruits were measured and the number of seeds counted. Tests were performed at the Banco de Sementes do Jardim Botânico de Porto AlegreSeeds were washed in tap water and dried on filter paper overnight. The seeds were then stored in polyethylene bags for seven days at room temperature, after which they were kept in plastic boxes (Gerbox) with blotting paper moistened with 10 mL of deionized water. Each box received 25 seeds with four replicates for each locality for a total of 100 seeds per locality/treatment. Seeds were subjected to one of three treatments, constant temperature of 20° C, 25° C or 30° C, in a germinator (Tecnal TE-4020 LED) with photoperiod of 12 h. A control test was made at room temperature (between 20.2 and 30.3 °C; average = 26.6 °C), with natural photoperiod. Germinated seeds were counted daily using a stereomicroscope. Seeds that emitted a visible hypocotyl-root axis were considered germinated.
Indexes calculated after the final count were: germinability as , where Ng is the number of germinated seeds and Nt is the total number of seeds; average germination time as , where ti is average incubation time and ni is the number of seeds germinated daily (Edmond & Drapalla 1958); and synchronization as , where fi is relative germination frequency (Labouriau & Valadares 1976). Final index values were compared by two-way ANOVA followed by Tukey’s significant difference test at 5 %. All statistical analyses were carried out using the software RStudio 1.2.1 (Allaire 2012).
Results
Ripe fruits are of the acrosarcum type with an average diameter of 6.5 ± 0.73 cm, an average length of 8.1 ± 1.5 cm (n = 15) and a globular to elliptical shape. The epicarp is spineless, smooth, slightly shiny and yellowish or reddish (Fig. 1A). The endocarp is white, fleshy and edible, with hundreds of very small seeds (Fig. 1B). Some very ripe fruits in the wild were observed to split and open, exposing the pulp and seeds, yet other fruits were consumed by birds without prior splitting (Becker, in. prep.). Fruits can hold between 500 and 1000 seeds (mean 787.7 ± 238.3; n = 15), which are darkish, campylotropous, kidney-shaped and bitegumented. The testa is ornate and the hilum possesses a micropylar depression (Fig. 2A). Germination begins between days 4 and 8 after seeding and proceeds for about a week. Seeds were considered germinated when the hypocotyl-root axis protruded from the hilum break (Fig. 2B).
Ripe fruit of Cereus hildmannianus (A); transversal section of ripe fruit of C. hildmannianus showing the edible endocarp and countless seeds (B). Scale: 1 cm.
Seed germination stages for Cereus hildmannianus. (A) general appearance of seed with hilum micropilar and ornate testa; (B) day 4 - emission of hypocotyl-root axis; (C) day 10 - chlorophyllous seedling with visible cotyledon; (D) day 20 - established seedling with areole and spines. Abbreviations: hm (micropilar hilum); hil (hilum); teg (testa); hyp (hypocotyl); pr (primordial root); cot (cotyledon); ep (epicotyl); r (rootlet); ar (areole); sp (spine). Scale: 1mm.
Seedlings are initially white and two short, conical cotyledons are visible on day 10, when the hypocotyl is completely straight. Later, seedlings turn greenish and are typically columnar-shaped and about 2 cm tall (Fig. 2C). Trichome and areole emission takes place around day 20, when the cotyledons disappear and the epicotyl becomes very developed (Fig. 2D).
All three calculated indexes differed significantly among temperatures as well as for the interaction between temperature and locality. Conversely, none of the indexes differed significantly among localities (Tab. 2).
Two-way ANOVA of germinability (G), average germination time (t) and synchronization index (E). Statistically significant values are marked with (*).
Germinability was considered high for all tests, since samples from all localities reached over 90 % germination at 20° C and 25° C. However, at 30° C seeds from Santiago and Caçapava do Sul had lower germination percentages, although significantly so only for Caçapava do Sul. Seeds from Porto Alegre had excellent germinability in all treatments.The average germination time index did not differ significantly among temperature treatments. Under the control treatment, however, seeds from Caçapava do Sul had a longer average germination time than did seeds from Santiago. The synchronization index differed significantly between seeds from Porto Alegre and seeds from Caçapava do Sul at 25° C and 30° C, and between seeds from Porto Alegre and seeds from Santiago at 30° C (Tab. 3).
Values of mean germinability (G), average germination time (t) and mean synchronization index (E) for seeds collected in Porto Alegre, Santiago and Caçapava do Sul at control, 20° C, 25° C and 30° C. Values with the same letter in a column do not differ significantly according to Tukey’s test at 5 %.
Discussion
Morphological characterization of seeds is very important for the taxonomy of Cactaceae. For instance, testa ornamentation patterns have been proven to be taxonomically informative among species of Stenocereus (Arroyo-Cosultchi et al. 2006). However, details about the seeds of native Brazilian cacti, and their potentially informative characters, are scarce in the literature. As a whole, fruit size and shape and seed features of C. hildmannianus are similar to those of C. jamacaru (Abud et al. 2013) and those of C. repandus (Mizrahi 2014; Ninio et al. 2003; as C. peruvianus). Yet, to date, seed features, germination, seedling features and early development have been studied in depth for only C. jamacaru (Abud et al. 2013). Abud et al. (2013) described the fruits of C. jamacaru with very similar dimensions as those found here for C. hildmannianus, yet with a higher number of seeds (mean 1439 ± 189.78; vs. 787.7 ± 238.3 in C. hildmannianus). The seeds of C. jamacaru were morphologically characterized as being darkish, kidney-shaped and bitegumented (Abud et al 2013), which is in agreement with the characters observed here for C. hildmannianus. The embryo of C. jamacaru, as in C. hildmannianus, occupies almost the entire space inside the seed, a common characteristic for Cactaceae (Carneiro et al. 2016). An ornate testa was also observed for C. jamacaru (Abud et al. 2013), and the two species probably have specific patterns, but we are unaware of such studies for species of Cereus. All in all, seedling features (overall shape and morphology), as well as early plant development, of C. hildmannianus are quite similar to those reported for C. jamacaru (Abud et al. 2013).
All samples of C. hildmannianus treated at 20° C and 25° C had high germinability rates (over 90 %), which is in agreement with data already reported for C. jamacaru with 89 % germinability at 25° C (Abud et al. 2013). All samples had shorter average germination times at 25° C. In practical terms, this means that germination is faster and more efficient at higher temperatures, but until a certain limit (Bewley & Black 1994). In fact, the best results in the present study were obtained at 25° C, while a decrease in germination time was observed at 30° C. Average germination time is an important variable because seeds that take a long time to germinate are usually more susceptible to diseases (Scremin-Dias et al. 2006) or may miss the climatic opportunity to grow. Thus, germination time can be used as an indicator of vigor.
As with average germination time, the synchronization index had lower values at 25° C. These results are similar to those found for Cereus fernambucensis (Socolowski et al. 2010), Pereskia aculeata and Pereskia grandifolia (Souza et al. 2016). These authors reported the same decrease in synchronization from 25° C to 30° C. Lower synchronization values for this temperature range should indicate an influence of external environmental factors, which is also reflected in higher germinability and germination speed (Labouriau & Osborn 1984). According to Souza et al. (2016), synchronization values increase above and below this temperature range (25° C to 30° C), and synchronization implies the establishment of a great number of seedlings with a better chance of survival. However, low synchronization could allow the species to germinate all seeds over a long period of time, thus avoiding a potential loss of all offspring in the case of an extreme weather event.
The synchronization index for seeds from Caçapava do Sul exposed to 25° C and 30° C and for seeds from Santiago at 30° C differed significantly from that for seeds from Porto Alegre under the same conditions. Whereas seeds from Porto Alegre maintained their germinative behavior in all treatments, those from Caçapava do Sul and Santiago exhibited variation in synchronization when exposed to the aforementioned temperatures.
Seeds from Porto Alegre had the best performance among the localities. In addition to the very similar synchronization indexes for Porto Alegre seeds, these seeds had the highest germination rate for each treatment (over 98 % germinated seeds), indicating that this population has the best vigor among the tested samples. The decrease in the synchronization index at 25° C for all populations is interesting for a species whose germination occurs over a long period of time, revealing its capacity to adapt to different environmental conditions that may vary during the course of a year. Seasons are highly marked in South Brazil, with a hot summer and a cold winter, in addition to well-distributed rainfall throughout the year (Pessoa 2017), and a wide range of temperatures can be favorable to germination for species adapted to such conditions. Although locality did not show any influence in the tests, the interaction between locality and temperature may be acting in the recovered results. This possible synergy may explain the good and stable behavior for seeds from Porto Alegre, and the significant variation in germination synchronicity for seeds from the other localities between 25° C and 30° C, besides the decrease in germinability for seeds from Caçapava do Sul at 30° C.
The effect of temperature in this experiment is evidenced by the decrease of the synchronization index in seeds from Caçapava do Sul and Santiago, at 25° C and 30° C respectively, and the decrease in germinability for the same populations at 30° C. In general, the results found herein for these populations were similar to what has been found for other columnar cacti, such as Pachycereus hollianus, Cephalocereus chrysacanthus, Neobuxbaumia tetetzo (Rojas-Aréchiga et al. 1998), Stenocereus queretaroensis (Barrera & Nobel 2003) Trichocereus terscheckii (Ortega-Baes & Rojas-Aréchiga 2007), Cereus fernambucensis (Socolowski et al. 2010), Pilosocereus pachycladus (Abud et al. 2010), C. jamacaru (Meiado et al. 2010; Abud et al. 2013), Pilosocereus aurisetus (Reis et al. 2012), and Melocactus sergipensis (Filho et al. 2019). The species in all of these studies had high germinability and low average germination time within a wide range of temperatures, with better performances around 25° C. As a rule, indexes normally decrease at temperatures near 30° C, except for Pilosocereus gounellei (Abud et al. 2012), which showed optimum germinability at this temperature. According to Meiado et al. (2010), decreased germinability at extreme temperatures may be of ecological importance, since seedling survival in these conditions is low. Even when tuna had peak germinability and germination speed at 25° C, the values found at 20° C and 30° C were also high, indicating that this species has a wide range of temperatures favorable for germination.
It is important to point out that, in spite of occurring in the same biome, plants from Porto Alegre and Santiago belong to a different subspecies than those from the other localities. Remarkably, all the indexes calculated for the two populations were statistically similar, except for the synchronization index at 30° C. The most different germinative behavior was for the Caçapava do Sul seeds, a population identified as C. hildmannianus subsp. hildmannianus on morphological grounds (Becker in. prep.), which likely presents haplotypes more similar to those of the Porto Alegre populations (Silva et al. 2018). This intermediate population showed more instability with germinability and synchronization at high temperatures.
Most seeds of Cactaceae have a good germination response over large temperature gradients, with optimal temperatures usually around 25° C (Rojas-Aréchiga & Vázquez-Yanes 2000). This broad gradient is characteristic of species adapted to semi-arid environments, as rapid germination indicates an ease of forming seedlings at different temperatures, thus increasing the chance of survival compared to species with closer cardinal temperatures (Souza et al. 2016).
Conclusion
Seeds of Cereus hildmannianus have an optimum germination temperature of 25° C, with higher germinability and lower average germination times at this temperature. Remarkably, the synchronization index decreased at 25° C as well, a fact that can be interpreted as an adaption to germination over long periods of time. In addition, seeds collected at Porto Alegre were close to maximum germinability and showed more stability for all indexes in all treatments, which means that this population had higher vigor than seeds collected at Santiago and Caçapava do Sul. Species with large geographic distributions are also related to large temperature ranges due to adaptions to different climates in which such species may occur (Larcher, 2000). Cereus hildmannianus occurs in South and Southeast Brazil, Uruguay and the Argentinean Pampa, a fact that indicates an ability to develop under different conditions. In agreement, the data recovered herein for germination rates under different conditions support that C. hildmannianus is highly adaptable, a finding that not only explains its broad distribution, but also indicates that this cactus should not be problematic for cultivation and domestication purposes.
Acknowledgements
We thank the Coordenação de Aperfeiçoamento de Pessoa de Nível Superior (CAPES) for financial support (n° 88882.439443/2019-01) and the Porto Alegre Botanical Garden for the support, structure and equipment that made this study possible. We thank the Sistema de Autorização e Informação em Biodiversidade (SISBIO) for the collecting permit (Nº 64504-1)
References
- Abud HF, Gonçalves NR, Pereira MDS, Pereira DDS, Reis RDGE, Bezerra AME. 2012. Germination and morphological characterization of the fruits, seeds, and seedlings of Pilosocereus gounellei Brazilian Journal of Botany 35: 11-16.
- Abud HF, Gonçalves NR, Reis RDGE, Pereira DDS, Bezerra AME. 2010. Germinação e expressão morfológica de frutos, sementes e plântulas de Pilosocereus pachycladus Ritter. Revista Ciência Agronômica 41: 468-474.
- Abud HF, Pereira MDS, Gonçalves NR, Pereira DDS, Bezerra AME. 2013. Germination and morphology of fruits, seeds and plants of Cereus jamacaru DC. Journal of Seed Science 35: 310-315.
- Albuquerque UP, Medeiros PM, Almeida ALS, et al 2007. Medicinal plants of the caatinga (semi-arid) vegetation of NE Brazil: a quantitative approach. Journal of Ethnopharmacology 114: 325-354.
- Allaire J. 2012. RStudio: integrated development environment for R. Boston, Massachusetts, Kaleidoscope Ic.
- Arroyo-Cosultchi G, Terrazas T, Arias S & Arreola-Nava HJ. 2006. The systematic significance of seed morphology in Stenocereus (Cactaceae). Taxon 55: 983-992.
- Barrera E, Noble PS. 2003. Physiological ecology of seed germination for the columnar cactus Stenocereus queretaroensis Journal of Arid Environments 53: 297-306.
- Barthlott W, Hunt DR. 1993. Cactaceae. In: Kubitzki K, Rohwer JG, Bittrich V. (eds.) Flowering plants· Dicotyledons. Berlin, Heidelberg, Springer. p. 161-197
-
BDMEP. 2020. Banco de Dados Meteorológicos para Ensino e Pesquisa. http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep 17Jul. 2020.
» http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep - Bewley JD, Black M. 1994. Dormancy and the control of germination. In: Bewley D, Black M. (eds.) Seeds. Boston, Springer. p. 199-271.
- Carneiro AM, Farias-Singer R, Ramos RA, Nilson AD. 2016. Cactos do Rio Grande do Sul. Porto Alegre, Fundação Zoobotânica do Rio Grande do Sul.
- Carneiro MRB, Dos Santos ML. 2014. Importância relativa de espécies com potencial uso medicinal na flora do Centro Oeste do Brasil. Fronteiras: Journal of Social, Technological and Environmental Science 3: 145-163.
- Carvalho NM, Nakagawa J. 2000. Sementes: ciência, tecnologia e produção. 4th. edn.Jaboticabal, FUNEP.
- Casas A, Barbera G. 2002. Mesoamerican domestication and diffusion. In: Nobel PS. (ed.) Cacti. Biology and Uses. California, University of California Press. p.143-162.
- Chaves AS, Zanin EM. 2011. Etnobotânica em comunidades rurais de origem italiana e polonesa do município de Erechim-RS. Perspectivas 36: 95-113.
- Chaves EM, Barros RF. 2015. Cactáceas: recurso alimentar emergencial no semiárido, nordeste do Brasil. Revista Gaia Scientia 9: 129-135.
- Edmond JB, Drapala WJ. 1958. The effects of temperature, sand and soil, and acetone on germination of okra seed. Proceedings of the American Society for Horticultural Science 71:428-434.
- Ferreira AG, Borghetti F. 2004. Germinação: do básico ao aplicado. Porto Alegre, Artmed.
- Filho ES, De Santana MC, Santos PAA, Souza RA. 2019. Germinação e aclimatização de Melocactus sergipensis Taylor & Meiado. Iheringia: Série Botânica 74: 1-5.
-
Flora do Brasil 2020 em Cconstrução. 2020. Jardim Botânico do Rio de Janeiro. Disponível em: Disponível em: http://floradobrasil.jbrj.gov.br/ 15 Apr. 2020
» http://floradobrasil.jbrj.gov.br/ - Kamakshi KT, Raveen R, Tennyson S, Arivoli S, Reegan AD. 2015. Ovicidal and repellent activities of Cereus hildmannianus (K. Schum.) (Cactaceae) extracts against the dengue vector Aedes aegypti L. (Diptera: Culicidae). International Journal of Mosquito Research 2: 13-17.
- Labouriau LG, Osborn JH. 1984. Temperature dependence of the germination of tomato seeds. Journal of Thermal Biology 9: 285-294.
- Labouriau LG, Valadares MB. 1976. On the physiology of seed of Calotropis procera Anais da Academia Brasileira de Ciência 42: 235-264.
- Labouriau LG. 1983. A germinação das sementes (No. 581.1 LAB). Washington, OEA-Serie de Biologia.
- Larcher W. 2000. Ecofisiologia vegetal. São Carlos, Editora Rima.
- Lucena CM, Costa GM, Sousa RF, et al 2012. Conhecimento local sobre cactáceas em comunidades rurais na mesorregião do sertão da Paraíba (Nordeste, Brasil). Biotemas 25: 281-291.
- Lucena CM, Lucena RFP, Costa GM, et al 2013. Use and knowledge of Cactaceae in Northeastern Brazil. Journal of ethnobiology and ethnomedicine 9: 1-11.
- Meiado MV, De Albuquerque LSC, Rocha EA, Rojas-Aréchiga M, Leal IR. 2010. Seed germination responses of Cereus jamacaru DC. ssp. jamacaru (Cactaceae) to environmental factors. Plant Species Biology 25: 120-128.
- Mizrahi Y. 2014. Cereus peruvianus (Koubo) new cactus fruit for the world. Revista Brasileira de Fruticultura 36: 68-78.
- Ninio R, Lewinsohn E, Mizrahi Y, Sitrit Y. 2003. Quality attributes of stored koubo (Cereus peruvianus (L.) Miller) fruit. Postharvest biology and Technology 30: 273-280.
- Ortega-Baes P, Rojas-Aréchiga M. 2007. Seed germination of Trichocereus terscheckii (Cactaceae): light, temperature and gibberellic acid effects. Journal of Arid Environments 69:169-176.
- Pasa MC, Soares JJ, Guarim GN. 2005. Estudo etnobotânico na comunidade de Conceição-Açu (alto da bacia do rio Aricá Açu, MT, Brasil). Acta Botanica Brasilica 19: 195-207.
-
Pesce LC. 2011. Levantamento etnobotânico de plantas nativas e espontâneas no RS: conhecimento dos agricultores das feiras ecológicas de Porto Alegre. http://hdl.handle.net/10183/35329 4 May. 2020
» http://hdl.handle.net/10183/35329 -
Pessoa ML. 2017. Clima do RS. Atlas FEE. Porto Alegre, Fundação de Economia e Estatística (FEE). http://atlas.fee.tche.br/rio-grande-do-sul/socioambiental/clima/ 4 May. 2020
» http://atlas.fee.tche.br/rio-grande-do-sul/socioambiental/clima/ - Pimienta-Barrios E, Nobel OS. 1994. Pitaya (Stenocereus spp., Cactaceae): an ancient and modern fruit crop of Mexico. Economic Botany 48: 76-83.
- Rech AR, Agostini K, Oliveira PE, Machado IC. 2014. Biologia da Polinização. Rio de Janeiro, Projecto Cultural.
- Reis MVD, Pego RG, Paiva PDDO, Artioli-Coelho FA, Paiva R. 2012. In vitro germination and post-seminal development of plantlets of Pilosocereus aurisetus (Werderm.) Byles & GD Rowley (Cactaceae). Revista Ceres 59: 739-744.
- Rojas-Aréchiga M, Vázquez-Yanes C, Orozco-Segovia A. 1998. Seed response to temperature of Mexican cacti species from two life forms: an ecophysiological interpretation. Plant Ecology 135: 207-214.
- Rojas-Aréchiga M, Vázquez-Yanes C. 2000. Cactus seed germination: a review. Journal of Arid Environments 44: 85-104.
- Santana MCD, Santos PAA, Ribeiro ADS. 2018. Levantamento etnobotânico da família Cactaceae no estado de Sergipe. Fitos 12: 41-53.
- Scremin-Dias E, Kalife C, Menegucci ZRH, Souza PRD. 2006. Produção de mudas de espécies florestais nativas: manual. Campo Grande, Universidade Federal de Mato Grosso do Sul.
- Silva GAR, Antonelli A, Lendel A, Moraes EDM, Manfrin MH. 2018. The impact of early Quaternary climate change on the diversification and population dynamics of a South American cactus species. Journal of Biogeography 45: 76-88.
- Silva VA. 2015. Diversidade de uso das cactáceas no nordeste do Brasil: uma revisão. Revista Gaia Scientia 9: 137-154.
- Socolowski F, Vieira DCM, Simão E, Takaki M. 2010. Influence of light and temperature on seed germination of Cereus fernambucensis Lemaire (Cactaceae). Biota Neotropica 10: 53-56.
- Souza LF, Gasparetto BF, Lopes RR, Barros IB. 2016. Temperature requirements for seed germination of Pereskia aculeata and Pereskia grandifolia Journal of Thermal Biology 57: 6-10.
- Taylor NP, Zappi DC. 2004. Cacti of eastern Brazil. Kew, Kew Royal Botanic Gardens.
Publication Dates
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Publication in this collection
22 Mar 2021 -
Date of issue
Oct-Dec 2020
History
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Received
04 June 2020 -
Accepted
06 Oct 2020