Research Article

 

Investigation of Eighteen Indonesian Mutant Rice Straw Varieties as Ruminant Roughage

 

Teguh Wahyono*, Wahidin Teguh Sasongko, Yunida Maharani, Dedi Ansori, Tri Handayani, Dadang Priyoatmojo, Afi Candra Trinugraha

Department of Agriculture, Center for Isotope and Radiation Application, National Nuclear Energy Agency of Indonesia (BATAN), National Research and Innovation Agency of Indonesia, Lebak Bulus Raya St. No. 49, Cilandak, South Jakarta, 12440, Indonesia.

 

Received | April 20, 2021; Accepted | July 08, 2021; Published | September 25, 2021

*Correspondence | Teguh Wahyono, Department of Agriculture, Center for Isotope and Radiation Application, National Nuclear Energy Agency of Indonesia (BATAN), National Research and Innovation Agency of Indonesia, Lebak Bulus Raya St. No. 49, Cilandak, South Jakarta, 12440, Indonesia; Email: teguhwahyono@batan.go.id

Citation | Wahyono T, Sasongko WT, Maharani Y, Ansori D, Handayani T, Priyoatmojo D, Trinugraha AC (2021). Investigation of eighteen Indonesian mutant rice straw varieties as ruminant roughage. Adv. Anim. Vet. Sci. 9(11): 1757-1764.

DOI | http://dx.doi.org/10.17582/journal.aavs/2021/9.11.1757.1764

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2021 Wahyono et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

Rice straw is an important roughage source for livestock in rice-producing countries (Wang et al., 2006). Rice straw also had an important rules as major energy source in the long dry season (Ansah et al., 2017). In Indonesia, although it contains high levels of lignin and silica, rice straw is the primary choice for small-scale farmers due to easily available and quite cheap (Wahyono et al., 2021). Farmers will depend on rice straw as local feed ingredients due to lack of green forage production, especially in the long dry season (Rahman et al., 2010). Over the past 40 years, National Nuclear Energy Agency of Indonesia (BATAN) has developed 33 rice varieties based on mutation breeding. Meanwhile, the selection process is only based on agronomic and grain aspects. It is necessary to had the new paradigm on rice genetic improvement as straw-fodder source for ruminant (Wahyono et al., 2021). Fodder value of rice straw had beneficial effect and significantly contribute to increase the small-scale farmers income (Virk et al., 2019). Furthermore, Virk et al. (2019) stated that the new rice cultivars releasing agents should include information about rice straw quality when introducing cultivars in areas where rice straw contributes significantly for ruminant forage.

 

Nutrient value screening studies of various rice straw have been reported by previous studies (Ansah et al., 2017; Dong et al., 2013; Rahman et al., 2010; Ravi et al., 2019; Subudhi et al., 2020; Virk et al., 2019; Wahyono et al., 2021; Wang et al., 2006). In previous study, Wahyono et al. (2021) highlighted that Ciherang as Indonesian national variety had higher nutrient values in rice straw than four mutant varieties (Atomita 1, Bestari, Inpari Sidenuk and Situ Gintung). However, there are still many Indonesian mutant rice varieties that have not been explored from a ruminant nutrition perspective. Therefore, this research needs to be explored. This study was designed to compare chemical composition, nutrient values and in vitro digestibility between rice straws from mutant and national varieties from Indonesia. The second objective was to determine the correlation between in vitro digestibility parameters and fibrous compounds in twenty-two Indonesian rice straw varieties.

 

MATERIALS AND METHODS

 

Rice cultivars and straw preparation

The eighteen mutant rice, one non-mutant variety and three national rice varieties (Table 1) were grown by the Center for Isotopes and Radiation Application (CIRA), National Nuclear Energy Agency of Indonesia (BATAN), South Jakarta, Indonesia in 2017-2019. Samples were obtained in triplicate from three replicate plots. The whole plant was hand-harvested 10 cm above the ground and straw was collected by removing the grains. Rice straw samples were placed in paper bags, dried in an oven at 60oC for 72 hours and grinded through 1 mm (mesh 18).

 

Analysis of rice straw quality

Ash, organic matter (OM), ether extract (EE) and crude protein (CP) contents were determined according to the method of the AOAC (2005). Fiber contents, such as neutral detergent fiber (NDF), acid detergent fiber (ADF) and acid detergent lignin (ADL) were determined according to methods by Van Soest et al. (1991). Rice straw nutrient composition analysis was carried out in three repetitions.

 

Table 1: Characterization of eighteen Indonesian mutant varieties and four non-mutant varieties with regards growth duration plant heights and parentages.

 

Variety	Growth duration (days)	Plant heights (cm)	Release year	Parentages/Irradiation dose	Reference
Atomita 3	120	105 – 120	1990	627/10-3/PsJ / 0.2 kGy	CIRA 2020
Atomita 4	110 – 120	110 – 120	1991	Cisadane / 0.2 kGy	CIRA 2020
Situgintung	110 – 140	105 – 115	1992	Seratus Malam / 0.1 kGy	CIRA 2020
Cilosari	110 – 120	110 – 125	1996	SM-268/Psj mutant x IR-36	CIRA 2020
Meraoke	110 – 120	120 – 125	2001	Atomita 4 x IR-64 / 0.2 kGy	CIRA 2020
Woyla	105 – 115	115 – 120	2001	Atomita 4 x IR-64 / 0.2 kGy	CIRA 2020
Kahayan	110 – 115	96 – 105	2003	Atomita 4 x IR-64 / 0.2 kGy	CIRA 2020
Winongo	115 – 120	110 – 115	2003	Atomita 3 x IR-64 / 0.2 kGy	CIRA 2020
Diah Suci	115 – 120	110 – 115	2003	Cilosari x IR-64 / 0.2 kGy	CIRA 2020
Yuwono	110 – 115	95 – 105	2004	IR-64 / 0.1 kGy	CIRA 2020
Mayang	115 – 120	90 – 100	2004	Cilosari x IR-64 / 0.2 kGy	CIRA 2020
Mira 1	115 – 120	105 – 110	2006	Cisantana / 0.2 kGy	CIRA 2020
Bestari	115 – 120	100 – 115	2008	Cisantana / 0.2 kGy	CIRA 2020
Inpari Sidenuk	103	104	2011	Diah Suci / 0.2 kGy	CIRA 2020
Inpari Mugibat	119	104	2012	Cimelati / 0.2 kGy	CIRA 2020
Suluttan Unsrat 1	112	101	2012	Super Win / 0.2 kGy	CIRA 2020
Suluttan Unsrat 2	111	99	2012	Super Win / 0.2 kGy	CIRA 2020
Tropiko*	114	106	2015	Koshihikari / IR 36	CIRA 2020
Mustaban	120 – 125	110 – 115	2018	Jembar / 0.2 kGy	CIRA 2020
Ciherang*	116 – 125	91 – 106	2000	IR18349-53-1-3-1-3/3 x IR19661-131-3-1-3//4 x IR 64	IAARD 2021
Inpari 30*	111	101	2012	Ciherang x IR 64 Sub1 x Ciherang	IAARD 2021
Inpari 32*	120	97	2013	Ciherang x IRBB64	IAARD 2021

*non-mutant varieties.

Hemicellulose compound were calculated using following equations:

 

Hemicellulose (%) = NDF(%) – ADF(%)

 

Nutrient value estimation

Relative feed values (RFV) was determined according to calculation described by Undersander et al. (1993), using following equations:

 

 

Dry matter digestibility (DMD)(%)= 88.9–(0.779 × %ADF)

 

 

Based on quality standard by the hay marketing task force of the American forage and grassland council, the RFV were represent forage score: reject (< 75), poor (75 – 86), fair (87 – 102), good (103 – 124), premium (125 – 151) and prime (> 151).

 

In vitro digestibility determination

In vitro true digestibility (IVTD) were determined according to in vitro digestibility procedure by Kilic and Gulecyuz (2017) using DaisyII incubator (ANKOM Technology Corp, Fairport, New York). Rumen fluids were collected from three bulls (Approximate average 24-36 months of age and 300 kg live weight) that were slaughtered at local abattoir in South Tangerang, Banten, Indonesia. Approximately 0.5 g (DM basis) straw sample were inserted into filter bag and placed inside digestion jar (25 pieces per jar). Rumen liquor (400 ml) were mixed with buffer solution (1200 ml) for each digestion jar and immediately incubated into DaisyII incubator at 39.5oC for 48 h. After completion of incubation, filter bags were rinsed with tap water and dried at 105oC for 3 h. All samples were analyzed for NDF with Ankom Fiber Analyzer (ANKOM Technology Corp, Fairport, New York). In vitro assay was carried out in three repetitions. In vitro true digestibility was determined by following equation:

 

 

Where IVTD: in vitro true digestibility; W1: filter bag weight; W2: sample weight; W3: final sample weight after NDF analysis; C: the correction of blank filter bag (final oven-dried bag weight/original blank filter bag weight; and DM (dry matter percentage).

 

Statistical analysis

Statistical analysis was performed using SPSS 25.0 (IBM, Armonk, New York, USA). The effect of variety on rice straw quality, nutrient values and in vitro digestibility was analyzed using one-way analysis of variance (ANOVA). Comparison of means between variety were determined using Duncan multiple range test (DMRT). Data of fibrous compounds (NDF and ADF) and IVTD were analyzed by pairwise correlation of variables using SPSS 23.0 (IBM, Armonk, New York, USA).

 

RESULTS AND DISCUSSION

 

Characterization of eighteen Indonesian mutant varieties and four non-mutant varieties

Atomita 1 is a mutant rice variety that was originally first developed by BATAN, which was obtained in 1982 (data was not presented). In this study, Atomita 3 was the oldest mutant variety, which was discovered in 1990 (Table 1). Meanwhile, the newest mutant variety is Mustaban. The radiation dose of 0.1 kGy and 0.2 kGy are the dose applied in rice plant breeding in Indonesia. Situgintung variety is a highland rice type that has a long groth duration (110–140 days). Most of the mutant varieties in Indonesia are lowland rice type. As presented in Table 1, ten rice cultivars are the results of breeding program from IR 64 variety. Specifically, for Tropiko, this non-mutant variety was obtained from Koshihikari x IR 36 breeding program.

 

Chemical composition and fiber fraction

Results on chemical composition and fiber fraction are shown in Table 2. Except EE, different varieties had significant differences on chemical composition and fiber fraction (p<0.05). Ash content average was from 19.93% to 35.30%; OM content was from 64.70% to 80.07%; CP content was from 3.13% to 6.78%; EE content was from 2.59% to 4.24%; NDF content was from 66.18% to 77.22%; ADF content was from 36.33% to 49.77% and hemicellulose content was from 21.67% to 33.84%.

 

The ash content of Situgintung and Inpari Sidenuk rice straw was the highest of all (35.30% and 34.15%). In contrary, the OM content was highest (p<0.05) in Ciherang (79.16%) and Inpari 30 (80.07%). Woyla and Ciherang had highest CP, 6.78% and 6.54%, respectively. The NDF content of Woyla and Winongo was the lowest of all (66.18% and 66.39%). Tropiko, as non-mutant variety from BATAN, had lower ADF content (36.34%) than Inpari 32 and Ciherang. The hemicellulose content of Inpari Mugibat was lower (21.67%) than all of three Indonesian non-mutant variety (Ciherang, Inpari 30 and Inpari 32).

 

Nutrient value estimation

The nutrient value estimation of twenty two Indonesian rice straw varieties are reported in Table 3. Because the differences of NDF and ADF fractions among all cultivars, significant difference (P<0.05) was observed for DMI,

 

Table 2: Mean chemical composition and fiber fraction of eighteen Indonesian mutant and four non-mutant rice straw varieties from Indonesia

 

Variety	Ash	OM	CP	EE	NDF	ADF	Hemicellulose
	% DM
Atomita 3	26.83bcd	73.17ghi	5.87g	2.91ab	75.15cde	46.07bcde	29.08cdef
Atomita 4	24.90b	75.10h	4.96f	3.66ab	68.98abc	40.88ab	28.10cde
Situgintung	35.30j	64.70a	3.96cd	3.80ab	74.73cde	49.77e	26.17abcd
Cilosari	30.92gh	69.08cd	3.71bcd	3.64ab	70.22abcde	43.24bcde	26.98bcd
Meraoke	28.63cdef	71.37efgh	3.85cd	3.06ab	74.04bcde	45.95bcde	28.09cde
Woyla	28.04cde	71.96fgh	6.78h	3.50ab	66.18a	41.15abc	25.03abcd
Kahayan	27.17cd	72.83gh	4.43e	3.52ab	72.36abcde	44.72bcde	27.64bcd
Winongo	30.32fgh	69.68cde	5.04f	4.24b	66.39a	41.95abcd	24.44abc
Diah Suci	26.76bcd	73.24ghi	3.67bcd	3.71ab	67.27ab	42.61abcd	24.66abc
Yuwono	27.08cd	72.92gh	5.24f	3.42ab	71.26abcde	42.24abcd	29.02cdef
Mayang	30.36fgh	69.64cde	3.91cd	2.84a	70.93abcde	45.29bcde	25.65abcd
Mira 1	26.55bc	73.45hi	4.96f	3.90ab	72.69abcde	42.74abcd	29.95defg
Bestari	31.62hi	68.38bc	3.48abc	3.66ab	72.88abcde	46.51bcde	26.37abcd
Inpari Sidenuk	34.15j	65.85a	3.89cd	3.10ab	71.44abcde	48.68de	22.76ab
Inpari Mugibat	28.87defg	71.13defg	4.11de	2.59a	69.72abcd	48.05cde	21.67a
Suluttan Unsrat 1	33.45ij	66.55ab	3.34ab	3.34ab	70.83abcde	45.74bcde	25.08abcd
Suluttan Unsrat 2	30.85gh	69.15cd	3.54abc	3.53ab	76.20de	48.54de	27.66bcd
Tropiko*	29.66efgh	70.34cdef	3.23ab	3.07ab	70.17abcde	36.34a	33.84g
Mustaban	27.79cde	72.21fgh	3.13a	3.14ab	70.30abcde	45.93bcde	24.37abc
Ciherang*	20.84a	79.16i	6.54h	2.96ab	72.46abcde	45.70bcde	26.75bcd
Inpari 30*	19.93a	80.07i	5.26f	3.87ab	74.62cde	41.41abc	33.20fg
Inpari 32*	28.25cdef	71.75efgh	3.46abc	3.82ab	77.22e	44.66bcde	32.56efg
SEM	0.467	0.467	0.159	0.087	0.509	0.522	0.468

OM (organic matter), CP (crude protein), EE (ether extract), NDF (neutral detergent fiber), ADF (acid detergent fiber), SEM (standard error of mean). Values in a column followed by a similar superscripts are statistically similar after the DMRT test at a level of confidence 95%.

 

DMD and RFV parameters. The DMI value in the range of 1.55 and 1.82 % of animal weight with the highest (P<0.05) reported in Woyla variety. Woyla, Winongo and Diah Suci also had higher DMI value than Inpari 30 and Inpari 32 (P<0.05). Tropiko variety had highest DMD estimation (60.59%; P<0.05), higher than non-mutant variety (Inpari 32 and Ciherang). The range of RFV was from 62.74 to 80.33 with seventeen varieties included in the reject class. Atomita 4, Woyla, Winongo, Diah Suci and Tropiko were only varieties included in the poor class, with the RFV range by 76.94 to 80.33.

 

In vitro true digestibility and relationship between chemical composition and digestibility of rice straw

The IVTD of twenty two rice straw varieties is presented in Figure 1. Among all varieties, the IVTD of Winongo and Woyla were the highest (P<0.05), 56.48% and 56.37%, respectively, but there were no significant differences with Tropiko and Diah Suci. In contrary, Inpari 30 and Inpari 32 had lowest IVTD value, 43.01% and 42.26%, respectively. As reported in Table 4, NDF content had significantly and strong negatively associated with IVTD (r = -0.793; P<0.01). The correlation between IVTD and ADF content also strong enough and significant (r = -0.430; P<0.05). The correlation between rice straw IVTD and ash, EE, CP, and hemicellulose were statistically non-significant.

 

Different varieties influence the chemical composition and fiber fraction

The aim of this study was to evaluate nutrient composition and fiber fraction for mutant and non-mutant rice straw varieties in Indonesia, as well as determining differences among varieties. Previous study demonstrated that the differences in chemical composition between varieties may be related to genetic expression characteristics, due to all varieties are grown under the similar environment conditions (Wahyono et al., 2021). Significant differences in forage quality relate to varietal variations in cell wall compounds (Huang et al., 2020). The similar findings also resulted by Rahman et al. (2010); Ravi et al. (2019); Subudhi et al. (2020); Virk et al. (2019) and Wahyono et al. (2021). Others also reported similar results in oat straw (Kafilzadeh and Heidary, 2013; Kafilzadeh et al., 2012); wheat straw (Joshi et al., 2019); maize stover (Homann-Kee et al., 2013; Zaidi et al., 2013); common vetch (Huang et al., 2020); field pea (Wamatu et al., 2017) and brassica (Keim et al., 2020).

 

Table 3: Nutrient value estimation of eighteen Indonesian mutant and four non-mutant rice straw varieties from Indonesia.

 

Variety	DMI	DMD	RFV
	% weight	%
Atomita 3	1.60ab	53.01abcd	65.68
Atomita 4	1.74bcde	57.05de	76.94
Situgintung	1.61ab	50.13a	63.03
Cilosari	1.71abcde	55.22abcd	73.44
Meraoke	1.62abc	53.10abcd	66.74
Woyla	1.82e	56.84cde	80.20
Kahayan	1.66abcde	54.06abcd	69.78
Winongo	1.81de	56.22bcde	79.12
Diah Suci	1.79cde	55.71bcde	77.07
Yuwono	1.68abcde	56.00bcde	73.15
Mayang	1.69abcde	53.62abcd	70.54
Mira 1	1.65abcd	55.61bcde	71.20
Bestari	1.65abcd	52.67abcd	67.54
Inpari Sidenuk	1.69abcde	50.98ab	67.21
Inpari Mugibat	1.72bcde	51.47abc	68.75
Suluttan Unsrat 1	1.69abcde	53.27abcd	69.96
Suluttan Unsrat 2	1.58ab	51.08ab	62.74
Tropiko*	1.71abcde	60.59e	80.33
Mustaban	1.71abcde	53.12abcd	70.33
Ciherang*	1.66abcde	53.30abcd	68.64
Inpari 30*	1.61ab	56.64bcde	70.64
Inpari 32*	1.56a	54.11abcd	65.34
SEM	0.012	0.407	0.907

DMI (dry matter intake), DMD (dry matter digestibility), RFV (relative feed value), SEM (standard error of mean), Values in a column followed by a similar superscripts are statistically similar after the DMRT test at a level of confidence 95%.

 

After fiber and silica, CP content represent the nutrient quality of rice straw (Wahyono et al., 2021). For mutant varieties, CP concentrations varies from 3.13% to 6.78%, while CP concentrations for non-mutant varieties are from 3.23% to 6.54%. Our results were similar to previous study by Wahyono et al. (2021) and Rahman et al. (2010). This differences might be influenced by leaf: Stem ratio in rice straw. As fiber sources, the important quality characteristics are the composition of NDF and ADF. The mean of NDF content of mutant varieties are ranging from 66.18% to 75.15%, while the ADF contents are from 40.88% to 48.68%. Most of the mutant varieties had lower NDF concentrations than Ciherang as national variety. Ciherang had high NDF and ADF concentration by 72.46% and 45.70% respectively, while Inpari 30 and Inpari 32 contains highest hemicellulose content (33.20% and 32.56%, respectively). Previous studies reported that the mean of NDF contents of rice straw in Indonesia varied from 69.84% to 73.35% (Wahyono et al., 2021) and 68.67% (Firsoni et al., 2019). The NDF and ADF contents of rice straw grown in Malaysia, with a similar climate location, are 80.80% and 58.90%, respectively (Nazli et al., 2018). Several studies also demonstrated that ADF value of rice straw was in the range of 25.30% to 38.80% (Wang et al., 2006); 41.38% to 46.32% (Rahman et al., 2010); 43.40% to 48.36% (Ansah et al., 2017) and 47.40% to 57.70% (Virk et al., 2019). The differences in nutrient composition between studies may be caused by the differences in stem: Leaf ratio, climate conditions during cultivation, soil management, crop maturity during harvesting and post-harvest handling management (Huang et al., 2020; Wahyono et al., 2021). Based on the overall fiber parameters, Woyla and Winongo had the lowest fiber content. Gene mutant in crop rice had beneficial effect on the nutrient value of rice straw (Wang et al., 2006). However, further investigations are needed to develop this beneficial gene.

 

 

It is interesting to note that, Tropiko, as non-mutant variety had low NDF and ADF contents (Table 2). This variety obtained from Koshihikari x IR 36 breeding program (Table 1). Less information is available in the literature of utilization of Koshihikari variety as livestock feed, but we assume that Koshihikari had beneficial gene to develop the new dual purpose rice variety. However, this assumption needs to be investigated further. Leaf Star variety, as recently improved rice cultivar from Koshihikari variety, produces a large straw biomass and had a large amount of non structural carbohydrate in straw (Ookawa et al., 2010). Previous study reported that Koshihikari leaves produce low oxalate content, so that the usage for livestock forage can be increased (Miyagi et al., 2019).

 

Differences in quality value predictions

Based on the practically in the field, it is necessary to predict the quality value based on the calculation of fiber fraction (Undersander et al., 1993; Wahyono et al., 2021). Relative feed value is commonly used in forage indexing to help ranking of potential energy intake of feed stuffs (Fekadu et al., 2017). Lower NDF and ADF value related to higher DMI, DMD and RFV estimations. Lower NDF value may result in low physical fill in the rumen over time, thus allows higher voluntary feed intake (Kafilzadeh et al., 2012). A low ADF content related to high digestibility on feed (Kilic and Gulecyuz, 2017). Dry matter intake, DMD and RFV associated with feed corvertion ratio (FCR) and daily gain on cattle (Nazli et al., 2018). In terms of RFV, the differences in rice straw variety have an impact on their biological values.

 

Except Atomita 4, Woyla, Winongo, Diah Suci and Tropiko, all rice straw varieties included in reject class forage. Similar to our results, Wahyono et al. (2021) reported that the range in RFV of five rice straws in Indonesia varied by 60.99-68.89. However, our study showed that four mutant rice varieties (Atomita 4, Woyla, Winongo and Diah Suci) had higher RFV than other studies (Fekadu et al., 2017; Firsoni et al., 2019; Wahyono et al., 2021). The differences in RFV between studies may be caused by the differences in crop maturity during harvesting and post-harvest handling management. Rice straw contain lower RFV than other forage. The RFV of sorghum, tropical native grass, Brachiaria decumbens and legume are from 112.44 to 144.65 (Wahyono et al., 2019a); 70.36 to 89.41 (Wahyono et al., 2019b); 74.83 to 84.17 (Suhaimi et al., 2017) and 123.71 to 161.03 (Sasongko et al., 2019), respectively. Jahansouz et al. (2014) reported that the RFV estimation of corn and sorghum are from 118.70 to 124.30 and 98.40 to 110.00, respectively. The nutrient value prediction by Undersander et al. (1993) is obtained from the Alfalfa standard value (Wahyono et al., 2021), thus rice straw will be included in the low-quality forage group. Although rice straw had low nutrient quality, it is particularly useful when high quality of forage are expensive and limited (Nazli et al., 2018).

 

Differences in In vitro true digestibility and its relationship with chemical composition and fiber fraction

It appears from IVTD content that Woyla and Winongo were superior to all national control varieties (Ciherang, Inpari 30 and Inpari 32). The IVTD values ranged between 46.98% and 56.48% in the mutant varieties and from 42.26% to 55.24% in the non-mutant varieties (Figure 1). In our study, rice straw containing high levels of NDF and ADF (Table 2) tended to produce low IVTD. The IVTD value had negative association with NDF and ADF compounds (Table 4). Similar results reported by Zaidi et al. (2013); Wamatu et al. (2017) and Ravi et al. (2019). Neutral detergent fiber content, particularly lignocellulose compounds had negative effect on ruminal degradation and total tract digestibility (Jayanegara et al., 2019). The NDF, ADF and silica are the negative traits that could reduce the digestibility of rice straw (Ravi et al., 2019). Conversely, the relatively higher in digestibility could be an indication that plant cell wall degradation was not impeded in some rice straw varieties, possibly due to less silica and lignin content (Ansah et al., 2017).

 

Table 4: Correlation between nutrient compounds of rice straws from 22 varieties and their IVTD.

 

	ash	EE	PK	NDF	ADF	Hemicellulose
IVTD(%)	0.233ns	0.114 ns	0.149ns	-0.793**	-0.43*	-323 ns

nsnon significant; *P<0.05; **P<0.01; IVTD (in vitro true digestibility), EE (ether extract), NDF (neutral detergent fiber), ADF (acid detergent fiber).

 

Apparently, the proportion of leaf-stem ratio in each rice variety also affect the value of IVTD, however this needs further analysis. The nutritive values of straws are dependent upon the proportion and quality of the stem (Wang et al., 2006). Differences in the digestibility of feedstuffs from different varieties not only due to chemical composition, but also to different stem, leaves and grain ratios (Kafilzadeh and Heidary, 2013). Based on the perspective of resistance to crop disease, low digestibility and high lignin content are also related to the characteristics of plants that are diseases resistant. High disease resistant varieties of crops may tend to have lower nutritive quality of straw (Wamatu et al., 2017). In our study, this phenomenon was demonstrated by Suluttan Unsrat 1 and Suluttan Unsrat 2 rice straw varieties.

 

Our results for IVTD value were similar to that reported by Firsoni et al. (2020) but lower than reported by Wahyono et al. (2020). The IVTD value in this study also lower than IVTD from tropical native grass and legume as reported by Wahyono et al. (2019b) and Sasongko et al. (2019). Rice straws are characterized by their higher ratio of structural carbohydrate (i.e. hemicellulose and cellulose) to readily fermentable carbohydrates, thus they have low energy availability for ruminal fermentation. The most limiting factor to the nutrient quality of rice straw is silica, and then lignin (Van Soest, 2006).

 

CONCLUSIONS AND RECOMMENDATION

 

As mutant varieties, Woyla and Winongo had low fiber content which is represented by low NDF and ADF values. The nutrient value and digestibility of Woyla and Winongo also significantly higher than other varieties. Tropiko, as non-mutant variety, also had relatively high nutrient value. It is revealed from this study that the digestibility of rice straw was negatively associated with NDF and ADF compounds. Utilization of rice straw as forage should be combined with other high nutrient value feed ingredients because of its relatively low nutrient value (reject-poor class). The results of this study can be used as a starting point for rice plant breeding in Indonesia, to produce high nutritious rice plant from a forage perspective.

 

ACKNOWLEDGEMENTS

 

The authors acknowledge financial support from Center for Isotope and Radiation Application (CIRA), National Nuclear Energy Agency of Indonesia (BATAN). This research was provided by the National Research and Innovation Agency of Indonesia (BRIN) through “Program Pendukung Beasiswa Saintek”. The authors would like to thank Dr. Sobrizal, Mrs. Ita Dwimahyani and Plant Breeding Laboratory Staff for their assistance in the rice field management.

 

NOVELTY STATEMENT

 

There are many Indonesian mutant rice varieties that have not been explored from a ruminant nutrition perspective. Our novelty resides in the point of view of investigating various rice straw varieties in Indonesia, especially mutant vs non-mutant. We found that Woyla and Winongo (mutant varieties) and Tropiko (non-mutant variety) had a good prospects for use as roughages

 

AUTHOR’S CONTRIBUTION

 

Teguh Wahyono designed the experiment, performed in vitro gas analysis, collected the data and wrote the first-draft article. Wahidin Teguh Sasongko supervised the experiment, conducted in vitro analysis and revised the manuscript. Yunida Maharani performed the chemical composition and in vitro gas analysis. Dedi Ansori prepared raw sample and performed the chemical composition analysis. Tri Handayani performed in vitro analysis and collected the data. Dadang Priyoatmojo supervised the experiment and prepared in vitro analysis. Afi Candra Trinugraha analyze the data and revised the manuscript.

 

Conflict of interest

The authors have declared no conflict of interest.

 

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