Bioscience Journal  |  2022  |  vol. 38, e38053  |  ISSN 1981-3163 
 

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Braulio Otomar CARON1 , Fábio Miguel KNAPP2 , Denise SCHMIDT1 , Velci Queiróz de SOUZA3 , 

Volmir Sergio MARCHIORO1 , Mauricio FERRARI4 , Carine MEIER5  
 
1 Department of Agronomic and Environmental Sciences, Federal University of Santa Maria, Frederico Westphalen, Brazil. 
2 Postgraduate Program in Agronomy, Federal University of Goiás, Goiânia, Brazil. 
3 Campus São Gabriel, Federal University of Pampa, São Gabriel, Brazil. 
4 Agricultural Production Coordinator, SLC Agrícola, Sapezal, Brazil. 
5 Celeste Gobbato State Technical School, Palmeira das Missões, Brazil. 

 
Corresponding author: 
Braulio Otomar Caron 
E-mail: otomarcaron@yahoo.com.br 
 
How to cite: CARON, B.O., et al. UFSM XIKA FW: sugarcane cultivar for southern Brazil. Bioscience Journal. 2022, 38, e38053. 
https://doi.org/10.14393/BJ-v38n0a2022-55832 

 
 
Abstract 
In Brazil, in view of the different soil and climatic conditions of the sugarcane-producing regions, a strategy 
of creating small breeding programs for the crop is being used. Since 2008, the sugarcane breeding program 
of the Federal University of Santa Maria (UFSM), has been developing new, better adapted and higher-
yielding sugarcane cultivars for the climate conditions of the southern region of Brazil. Cultivar UFSM XIKA 
FW was developed at the Laboratories of Agroclimatology and Genetic Breeding and Plant Production of the 
UFSM, Campus Frederico Westphalen. It is the first mutation-induced sugarcane cultivar that was protected 
by the Ministry of Agriculture, Livestock and Food Supply, Brazil. The genotype used for mutation induction 
was cultivar IAC 87-3396, due to its good performance characteristics in the southern region. The mutation 
mechanism was induced in 2011, by immersing individual buds in a solution of the chemical mutagenic agent 
methyl methane sulfonate. The best genotypes were selected and tested in plant cane in 2013 and 2018 and 
in ratoon cane trials in 2014 and 2015. The new cultivar has a higher sugar production potential, and the 
mean yield of four years was 8.2 t ha-1 higher than that of the control, indicating a high yield potential. 
 
Keywords: Mutagenic agents. Plant breeding. Saccharum spp.  
 
1. Introduction 
 

In Brazil, the different soil and climatic conditions of the sugarcane producing regions have led to a 
strategy of creating small breeding programs for the crop. This approach allows the selection of genotypes 
adapted to different environments, with production gains at the national level, since breeding in specific 
environments can shorten the development period of cane cultivars (Dinardo-Miranda et al. 2008). 

According to Maluf et al. (2008), sugarcane is being cultivated in Rio Grande do Sul for a variety of 
purposes, for example, fodder, spirits, muscovado, and jaggery production, mostly without taking climatic 
factors and agronomic aspects into consideration. With the increasing demand for research, after the 
establishment of an Agricultural Zoning for sugarcane for ethanol production in 2008, research investments 
in the crop increased, to optimize cultivation and reduce the dependence on sugarcane-derived products 
from other Brazilian states.  

UFSM XIKA FW: SUGARCANE CULTIVAR FOR SOUTHERN 
BRAZIL 

https://orcid.org/0000-0002-6557-3294
https://orcid.org/0000-0002-9964-1101
https://orcid.org/0000-0002-9963-4956
https://orcid.org/0000-0002-6890-6015
https://orcid.org/0000-0003-3873-9567
https://orcid.org/0000-0002-9953-9844
https://orcid.org/0000-0003-0803-7134


Bioscience Journal  |  2022  |  vol. 38, e38053  |  https://doi.org/10.14393/BJ-v38n0a2022-55832 

 

 
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UFSM XIKA FW: sugarcane cultivar for southern Brazil 

Since 2008, the sugarcane breeding program of the Federal University of Santa Maria (UFSM), 
Campus Frederico Westphalen, has developed cultivars that are better adapted to the meteorological 
conditions of the southern region. Along the same line of sight, Maluf et al. (2008) and Cardoso and Sentelhas 
(2013), describe an increase in the world demand for sugar and ethanol, which will be pushing the area 
cultivated with sugarcane into agronomically and economically less privileged regions. In this sense, the 
objective of developing new cultivars for the southern region is highly topical. 
 
2. Material and Methods 
 

Cultivar UFSM XIKA FW was developed at the Federal University of Santa Maria, Campus Frederico 
Westphalen (27º39'56 "LS / 53º42'94" LW, at 490 m asl. The soil of the region is classified as Latossolo 
Vermelho Alumino Férrico (Embrapa 2006). According to Köppen's classification, the climate is Cfa (Alvares 
et al. 2013). 

The genotype used for mutation induction was IAC87-3396. It was chosen for standing out among 19 
sugarcane genotypes (IACSP93-6006, IAC91-2218, IAC87-3396, IAC91-5155, IAC91-2195, RB 855453, RB 
855506, Nova Irai, Ligeirinha Roxa, Pernambucana, SP 716163, RB 785750, NA 56-79, IAC91-5035, RB 
835089, RB 765418, Preguiçosa, Tucumã and Palhuda), for the traits Brix in cane juice (Consecana 2006) and 
stem weight per hectare, calculated by extrapolating the number of stems per meter and fresh stem weight 
to t ha-1, according to the row spacing, assessed in the growing seasons of 2008, 2009 and 2010.  

Mutation was induced in 2011, by immersing buds (stem length 3cm) separately in a 5-ppm solution 
of the chemical mutagenic agent Methyl Methane Sulfonate (MMS) for 12 hours, after which they were 
washed with distilled water to remove the rest of the agent. Thereafter, they were placed for one hour in 
200 mg L-1 indole acetic acid, to stimulate bud rooting and then transferred to a sand bed in a greenhouse, 
where they were left to grow to a height of 0.3 m for approximately 60 days, and then transplanted to the 
field, still in 2011. 

The best genotypes were selected and tested in plant cane in 2013 and 2018, and in ratoon cane 
trials (second cut) in 2014 and 2015. In the field experiment, the mutants were distributed in a randomized 
block design with four replications. Each plot consisted of four 4-meter rows spaced 1.2 meters apart, at a 
plant spacing of 1.0 meter. The plants grown on two meters of the two central rows were used for analysis 
of the productivity variables and two stems per plot for soluble solids analysis. For all growing seasons, the 
seedlings were produced in a greenhouse in June, transplanted to the field in October and harvested in May, 
before chilling. Fertilization was applied, according to the technical indications for the crop in the states of 
RS and SC (Sociedade Brasileira de Ciência do Solo 2004). Pests and diseases were not controlled, and weeds 
were controlled by hand weeding. 

The following traits were traits analyzed in 2013, 2014, 2015 and 2018: Brix of the base, middle and 
apex parts of the plant, where the Brix levels were determined with a refractometer (Consecana 2006); Brix 
in cane juice, quantification of the juice soluble solids, with a refractometer (Consecana 2006); number of 
stems per meter in the plant row; stem weight, measured as the mean weight of two stems on an analytical 
scale; and stem yield, calculated by extrapolating number of stems per meter and fresh stem weight to t ha -
1, according to the row spacing. 

Based on these data, a new cultivar with the desired traits was selected and protected by the Ministry 
of Agriculture, Livestock and Food Supply (MAPA, no. 20160021-SNPC), after field evaluations in 2013, 2014 
and 2015. Thereafter, the new cultivar was evaluated in 2018 in Frederico Westphalen and will be tested in 
2019 and 2020 at two locations in Rio Grande do Sul before registration for cultivation. 
 
3. Results and Discussion 
 

Cultivar UFSM XIKA was the first sugarcane cultivar obtained by induced mutation in Brazil that was 
protected by the Ministry of Agriculture, Livestock and Food Supply. The new cultivar is clearly 
distinguishable from the cultivar of origin (IAC87-3396), based on differences in stem color, length and shape 
and amount of wax. The node color differs in the ring and waxy zone, aside from differences with regard to 



Bioscience Journal  |  2022  |  vol. 38, e38053  |  https://doi.org/10.14393/BJ-v38n0a2022-55832 

 
 

 
3 

CARON, B.O., et al. 

bud protrusion, leaf blade width, auricle type, blade joint color, amount of hairiness of the lea f sheath and 
sugarcane heart length.  

Analysis of variance detected no interaction between cultivar and year (p<0.05), for any of the 
evaluated traits. There was a significant difference between cultivars for Brix of the plant base, Brix of the 
middle plant third, number of stems per meter and stem weight. For the traits Brix of the plant apex, Brix in 
juice and stem yield there was no significant difference. 

The means of the traits for the two cultivars (Table 1) showed that the total soluble solids parameters 
(Brix degrees) of cultivar UFSM XIKA FW were higher than of IAC87 3396 (1° Brix of the plant base and 0.7 
° Brix of the middle plant third), indicating that cultivar UFSM XIKA FW is more promising for sugar 
production than cultivar IAC87 3396. These results are important, for example, with a view to the planning 
of sugar and ethanol production. 

 
Table 1. Performance of cultivar UFSM XIKA FW with regard to Brix of the plant base (BB), Brix of the middle 
plant third (BM), Brix of the plant apex (BA), Brix in juice (BJ); number of stems per meter (NS), stem weight 
(SW) and stem yield (YD) in the 4-year test means. Frederico Westphalen, RS, 2020. 

Cultivar 
BB 
- 

BM 
- 

BA 
- 

BJ 
- 

NS 
(Unit) 

SW 
(g) 

YD 
(t ha-1) 

UFSM XIKA FW 19.5a 18.9a 16.7ns 18.0ns 15.9a 1683.8b 176.4a 
IAC87-3396 18.5b 18.2b 16.0 17.5 12.9b 1942.6a 168.2a 

CV (%) 3.01 4.12 12.62 3.34 16.20 17.05 19.93 
Means followed by the same lowercase letter in a column do not differ significantly from each other by the Scott & Knott grou ping test at 5% 
error probability. ns - not significant. 
 

The yield of the new cultivar was directly related to the number of stems per meter and stem weight.  
The values of these traits were significantly higher than those of the control cultivar. This confirms the results 
of Brasileiro et al. (2013), where a direct correlation between the number of stems and stem weight and 
yield was reported. In the 4-year mean, the yield of cultivar UFSM XIKA FW was higher, demonstrating a high 
yield potential, but not significantly different from that of the control. 

The descriptors used in the evaluation procedures for protection showed that cultivar UFSM XIKA FW 
has an upright growth habit and tall plant height, dark green leaves and a broad leaf blade, generating a 
dense leaf volume, that contributes to a good row canopy closure, protecting the buds and suppressing 
weeds. 
 
4. Conclusions 
 

Cultivar UFSM XIKA, first sugarcane cultivar obtained by induced mutation in Brazil, with higher Brix 
of the plant base, Brix of the middle plant third and number of stems per meter in relation to the control. 
 
Authors' Contributions: CARON, B.O., SCHMIDT, D., SOUZA, V.Q., MARCHIORO, V.S.: conception and design, analysis and interpretation of data, 
and drafting the article; KNAPP, F.M., FERRARI, M; MEIER, C.: conducting, obtaining data, analysis and interpretation data, drafting the article. All 
authors have read and approved the final version of the manuscript. 
 
Conflicts of Interest: The authors declare no conflicts of interest. 
 
Ethics Approval: Not applicable. 
 
Acknowledgments: Federal University of Santa Maria. 
 
 
References 
 
ALVARES, C.A., et al. Köppen's climate classification map for Brazil. Meteorologische Zeitschrift. 2013, 22(6), 711-728. 
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BRASILEIRO, B.P., PETERNELLI, L.A. and BARBOSA, M.H.P. Consistency of the results of path analysis among sugarcane experiment s. Crop 
Breeding and Applied Biotechnology. 2013, 13(2), 113-119. https://doi.org/10.1590/S1984-70332013000200003 
 
CARDOSO, N.P. and SENTELHAS, P.C. Climatic effects on sugarcane ripening under the influence of cultivars  and crop age. Scientia Agricola. 
2013, 70(6) 449-456. https://doi.org/10.1590/S0103-90162013000600011 

https://doi.org/10.1127/0941-2948/2013/0507
https://doi.org/10.1590/S1984-70332013000200003
https://doi.org/10.1590/S0103-90162013000600011


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UFSM XIKA FW: sugarcane cultivar for southern Brazil 

 
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Received: 1 July 2020 | Accepted: 12 October 2021 | Published: 12 August 2022 
 
 

 
 
  

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