Physical treatment and protease or probiotic supplementation and feather meal digestibility by broilers

Y. M. Sun; X. Li; D. Zhang; W. L. Bryden

doi:10.1071/AN24091

RESEARCH ARTICLE (Open Access)

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Physical treatment and protease or probiotic supplementation and feather meal digestibility by broilers

Y. M. Sun

^A ^* , X. Li

^A , D. Zhang ^A and W. L. Bryden

^A ^B

+ Author Affiliations

- Author Affiliations

^A School of Agriculture and Food Sustainability, The University of Queensland, Gatton, Qld 4343, Australia.

^B Queensland Alliance for Agriculture and Food Innovation, The University of Queensland, Gatton, Qld 4343, Australia.

^* Correspondence to: yiman.sun@uq.net.au

Handling Editor: Teck Loh

Animal Production Science 64, AN24091 https://doi.org/10.1071/AN24091

Submitted: 20 March 2024 Accepted: 20 April 2024 Published: 16 May 2024

© 2024 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Context

Improving the utilisation of alternative protein ingredients in livestock production will reduce feeding costs and improve industry sustainability. Feather meal (FM) is an abundant, alternative protein source with a high protein content but poor amino acid (AA) digestibility.

Aim

This study evaluated strategies for improving AA digestibility of FM.

Methods

Experiment 1 examined the effects of physical treatment with ultrasound, microwave and autoclaving on FM AA profile and digestibility. Experiment 2 evaluated the dietary addition of a protease (Ronozyme ProAct, 200 and 600 mg/kg; RPA) and a probiotic (BioPlus 400, 1500 mg/kg) on FM AA digestibility. Apparent ileal digestibility was determined by feeding each treatment to four replicate groups of six birds in Experiment 1 and five replicate groups of seven birds in Experiment 2, and then collecting the contents of the lower half of the ileum.

Key results

None of the physical treatments improved (P > 0.05) the AA profile or ileal AA digestibility of FM. Dietary supplementation with RPA at 200 mg/kg or BioPlus 400 at 1500 mg/kg did not significantly (P > 0.05) influence the apparent ileal AA digestibility of FM. However, the higher concentration of RPA (600 mg/kg) significantly (P < 0.05) increased the apparent ileal AA digestibility of FM.

Conclusion

The increased digestibility of FM by the protease and numerical increase (P < 0.1) by the probiotic (1500 mg/kg) presumably reflects keratinase activity of both feed supplements.

Implications

The results of this study indicated that there is scope for further improvement in the nutritive value of FM for broilers.

Keywords: amino acid digestibility, autoclave, broilers, feather meal, microwave, probiotic, protease, ultrasound.

Introduction

Hydrolysed feather meal (FM) is a major by-product of the poultry industry and is potentially a valuable source of crude protein and amino acids (AAs; El Boushy et al. 1990; Polin 1992). Attempts have been made in Australia for many years to increase the use of FM in both broiler (MacAlpine and Payne 1977) and layer (Luong and Payne 1977) diets. However, the major constraint is keratin, a feather protein, containing disulfide bonds, which form a tight network structure that hinders the proteolytic degradation of keratin by intestinal proteases, thus reducing FM digestibility (Parry and North 1998; Kreplak et al. 2004). Feather meal is considered a low-quality protein for broilers because of low digestibility, reduced feed intake, and an imbalance of nutrients, which result in poor utilisation (Cherry et al. 1975; Onifade et al. 1998; Ravindran et al. 1999).

To improve the feeding value of FM, many technologies (physical, chemical, and biological) have been reported and each process has pros and cons in terms of feather degradation and industrial application (Latshaw et al. 1994; Grazziotin et al. 2006; Lee et al. 2016; Li 2019). Physical technologies that have been shown to improve the efficiency of protein hydrolysis include microwave, ultrasound and autoclave (Li et al. 2010; Zoccola et al. 2012; Dai et al. 2020). Processing with microwaves has been used as a novel physical method to increase protein digestibility of feed ingredients (Chen et al. 2014; Sun et al. 2020). Sun et al. (2020) reported that microwave cooking of pigeon pea flour for 3 min resulted in a significant increase of 17.2% in protein hydrolysis compared with the raw sample. Lee et al. (2016) reported that microwave heating could denature keratin by disrupting both the secondary and tertiary structures of keratin and Rodríguez-Clavel et al. (2019) demonstrated that microwave or ultrasound irradiation could induce the recrystallisation stage of feather keratin. Moreover, the effect of microwave or ultrasound irradiation on modifying the texture and morphology of materials depends on the exposure time and power level (Rodríguez-Clavel et al. 2019). Ultrasonic waves change protein conformation, which exposes more hydrophobic groups, thus increasing protein solubility (Patist and Bates 2008). However, we are not aware of any reports that compare these different physical treatments on FM utilisation in poultry.

There has been much interest in supplementation of poultry diets with exogenous feed enzymes to improve digestibility (Bedford and Morgan 1996; Ravindran 2013). It has been shown that proteases can improve protein digestibility and reduce the need for supplementation of poultry diets with first limiting AAs (Zheng et al. 2023). Furthermore, protease is critical for optimising the use of alternative protein sources (Cowieson and Roos 2016), including poultry by-products (Lindberg et al. 2021). Keratinase, which is a specific protease that degrades insoluble keratin substrates, especially disulfite bonds, has attracted much attention as a potential way to improve the nutritional value of FM (Onifade et al. 1998; Brandelli et al. 2010). The use of keratinases with FM not only improves nutritive value in terms of digestibility but also the biochemical composition (Grazziotin et al. 2006). Recently, Ronozyme® ProAct (RPA) was introduced for broiler feed supplementation as a novel pure serine protease expressed in Bacillus licheniformis that has shown promising results when tested in vitro and in some in vivo studies (Glitsø et al. 2012; Navone and Speight 2018).

The ability of probiotics to enhance nutrient digestibility and growth performance of poultry has been shown in many studies (Saleh et al. 2020a; Zaghari et al. 2020; Bajagai et al. 2023) but the effect of probiotics in FM-based poultry diets has not been reported. Bacillus is one of the major probiotic genera used in poultry nutrition (Shini and Bryden 2022). BioPlus 2B® is a Bacillus probiotic (contains B. subtilis and B. licheniformis spores), and several studies using it have shown improved growth, nutrient utilisation and carcass characteristics of broilers (Šabatková et al. 2008; Bai et al. 2013). Bacillus licheniformis and B. subtilis produce enzymes in the intestine such as amylase, protease, and lipase. Some proteases have the ability to hydrolyse keratin (Brandelli 2008; Daroit et al. 2010; Kaewtapee et al. 2017). BioPlus 400 is an in-feed probiotic containing B. subtilis and B. licheniformis, as does BioPlus® 2B (Liu et al. 2012). Interestingly, most commercial keratinase enzymes are produced from B. licheniformis (Navone and Speight 2018). It is possible therefore, that BioPlus 400 has the potential to hydrolyse feather proteins and improve the nutritional value of FM. Moreover, the keratinous substrates in FM may induce keratinase production by B. licheniformis (Mazotto et al. 2011).

The aims of the current in vivo studies in broiler chickens were to (1) determine the effect of different physical treatments on AA digestibility of FM, and (2) evaluate the dietary addition of a protease and a probiotic on AA digestibility of FM. The findings will provide guidance for further studies to improve FM utilisation by broilers.

Materials and methods

Physical treatment of feather meal

The hydrolysed FM used in this study was supplied by CSF Proteins Melbourne (1–9 Merino Street, Laverton, Victoria, Australia). After the physical treatment (ultrasound, microwave and autoclave) as described below, the FM samples were oven-dried at 60°C and then ground to a particle size of 2 mm in a Wiley Mill (Thomas Scientific, USA). The FM samples were then stored in a cool room at 14°C and subsampled for protein and AA analysis.

Ultrasound

The ultrasound treatment was conducted in an ultrasonic cleaner FXP14 (Unisonics®, Australia) with a frequency of 40 kHz in pulse mode. Feather meal samples were mixed with deionised water at a solid:liquid ratio of 1:2 in glass bottles with screw caps and sonicated for 30 min or 120 min.

Microwave

Feather meal samples were added to deionised water at a solid:liquid ratio of 1:2 in a microwave container and subjected to microwaves at residence times of either 2 min or 10 min. Microwave treatment of FM was conducted using a domestic microwave oven (Anko, P11034AL-B6), with an operating frequency of 2450 MHz and power level of 1100 W.

Autoclave

The FM samples were mixed with distilled water at a solid:liquid ratio of 1:2 in autoclave bags and placed in an autoclave (Athena Autoclave TA10364345). The operating conditions for the autoclave treatment were 120°C and 120 kPa for a run time of 45 min.

Birds

Day-old, male broiler chicks (Ross 308) were obtained from a local hatchery. The chicks were reared in an environmentally controlled room where the temperature was maintained at 32 ± 1°C during the first week and gradually decreased to ~23°C by the end of the third week. The birds received a commercial broiler starter diet (230 g protein/kg) from Day 1 to 20 and a commercial broiler finisher diet (180 g crude protein/kg) from Day 21. The experimental procedures involving birds were approved by the Animal Care and Ethics Committee of the University of Queensland and complied with the Australia Code of Practice for the Care and Use of Animals for Scientific Purposes (NHMRC 2013).

Digestibility bioassay

The bioassay procedure, used in both experiments, has been described by Ravindran et al. (1999). Briefly, on Day 35, birds with bodyweights close to the mean were selected and randomly allocated into cages and fed experimental diets. These diets were based on the basal control diet, shown in Table 1, where FM was the sole source of dietary protein in all experimental diets. Celite® (Celite Corporation, Lompoc, CA, USA), a source of acid insoluble ash (AIA), was added (20 g/kg) to all diets as an indigestible marker. The fibre component of the diet was satisfied by adding cellulose (Solkafloc®, James River Co., New Jersey, USA). After 5 days of feeding, all birds were euthanased by cervical dislocation and digesta from the lower half of the ileum was collected by gently flushing with distilled water. The digesta from all birds in the same pen were pooled and stored at −20°C prior to freeze-drying and grinding to pass a 0.5 mm sieve.

Table 1.Composition of the basal diet (g/kg DM) for digestibility bioassays.

Ingredient	Basal diet
Feather meal	285.7
Dextrose	563.3
Canola oil	60
Celite	20
Dicalcium P	19
Limestone	10
Choline chloride	3
Salt	2
Solkafloc	30
Premix ^A	7
Total	1000

^A Each kg of premix contained the following: vitamin A, 4.8 MIU.; vitamin D3, 0.96 MIU.; vitamin E, 10 g; vitamin K3; 0.8 g; riboflavin (vitamin B2), 5 g; pyridoxine (vitamin B6), 2.4 g; cyanocobalamin (vitamin B12), 6 mg; biotin, 0.06 g; niacin, 24 g; thiamine (vitamin B1); 0.8 g; pantothenic acid, 6 g; folic acid, 0.6 g; magnesium (Mg), 40 g; manganese (Mn), 40 g; zinc, 32 g; iron, 32 g; copper, 4 g; iodine, 0.2 g; cobalt, 0.04 g; selenium, 0.04 g; molybdenum, 0.04 g; Endox, 50 g and Liquid Paraffin white, 10 g.

In Experiment 1, each experimental diet was fed to four cages of six birds per cage for 5 days. The six experimental dietary treatments involved feeding the physically treated FM as described in Table 2.

Table 2.Dietary treatments fed to broilers in Experiment 1.

Diet/treatment	Treatment method
1. Control	n.a.
2. U30	Ultrasonic treatment for 30 min
3. U120	Ultrasonic treatment for 120 min
4. M2	Microwave treatment for 2 min
5. M10	Microwave treatment for 10 min
6. Auto	Autoclaved treatment

In Experiment 2, each experimental diet was fed to five cages of seven birds per cage for 5 days. The four experimental dietary treatments examined in Experiment 2 are shown in Table 3. The basal or control diet was Diet 1, and Diets 2 and 3 consisted of the control diet supplemented with two protease, Ronozyme® ProAct (DSM, Switzerland) at two concentrations of 200 mg/kg and 600 mg/kg respectively. Diet 4 consisted of the control diet supplemented with the probiotic BioPlus 400® (Chr. Hansen, Denmark) at 1500 mg/kg.

Table 3.Dietary treatments fed to broilers in Experiment 2.

Diet/treatment	Basal diet + additive	Supplement or species	Spore number per kilogram of feed
1. Control	Diet 1*	n.a.	n.a.
2. Enzyme 1	Diet 1 + RPA 200	Ronozyme® ProAct	n.a.
3. Enzyme 2	Diet 1 + RPA 600	Ronozyme® ProAct	n.a.
4. Probiotic	Diet 1 + BioPlus®	B. subtilis B. licheniformis	3.2 × 10⁵ 3.2 × 10⁵

*Diet 1 composition see Table 1.

Chemical analysis

The AA contents of FM and ileal digesta were determined as described by Cai et al (2022). Briefly, the protein sample (50 mg) was hydrolysed under nitrogen with 6 mol/L hydrochloric acid containing 5 mL dithiothreitol (DTT; 20 mM) at 110°C overnight. DTT is an unusually strong reducing agent and used to is reduce the disulfide bonds of proteins and to prevent intramolecular and intermolecular disulfide bonds from forming among cysteine residues of proteins. Hydrolysates were evaporated to dryness with a rotary evaporator (BUCHI Rotavapor® R-300) to remove residual HCl. The dried sample was dissolved in 5 mL 0.1% formic acid and collected in a syringe and filtered through a 0.22-μm pore nylon filter membrane (Alltech, Baulkam Hills, NSW, Australia) into injection vials.

A Shimadzu LC-MS 8050 analyser (Shimazu Co., Kyoto, Japan) was used for AA analysis. The samples were diluted in 0.1% formic acid in MS-grade water and injected onto a F5 column (Sigma-Aldrich, Australia). Ions were detected in positive mode and monitored using targeted multiple-reaction monitoring (MRM) approach, that is also known as selective reaction monitoring. It is a highly specific and sensitive mass spectrometry technique that can selectively quantify compounds within complex mixtures. Spectra results obtained from mass spectrometry were processed using the software package Skyline (v20.2.1.286, AB Sciex). Each amino acid was quantified using a standard curve generated from known standards. Amino acid analyses were conducted in duplicate.

Dry matter (DM) was determined by drying samples at 105°C for 48 h. Nitrogen content was determined by using a FP-428 nitrogen analyser (LECO®, St Joseph, MI, USA) (Sweeney 1989). The AIA contents of diet and digesta samples were determined after ashing the samples and boiling the ash with 4 M hydrochloric acid (Li et al. 2006).

Calculations

Ileal digestibility of protein and AAs was calculated using AIA as an indigestible marker, as follows:

%Ileal digestibility = [(N_{ing} \times diet inclusion level) / {AIA}_{d} - (N_{ileal} / {AIA}_{ileal})] / (N_{ing} × diet inclusion level) / {AIA}_{d} × 100%

where diet inclusion level = the level of FM in complete diet, N_ing = nutrient concentration in the FM, and N_ileal = nutrient concentration in the ileal digesta; AIA_d = acid insoluble in the diet, and AIA_ileal = acid insoluble in ileal digesta.

Percentage DM was calculated as

%DM = (Dry weight of sample) / (Wet weight of sample) \times 100

Statistical analyses

All data were subjected to ANOVA by using Minitab Software ver. Pl18 (The University of Queensland). Treatment means were separated using Tukeys’ pair-wise comparison procedure. Means were compared and considered significant when P ≤ 0.05, although probability values up to P < 0.10 were considered if the data suggest a trend.

Results

Composition of FM before and after physical treatment

As shown in Table 4, the DM content was highest after autoclaving in (6-Auto, 93.2%) and lowest following ultrasound (2-U30, 89.5% and 3-U120, 89.9%). Crude protein content was highest (P < 0.05) after autoclaving (2-U30, 91.1%), while the lowest value was recorded after microwaving (4-M2, 89.5%).

Table 4.Crude protein and amino acid composition (g/kg DM) of feather meal following different physical treatments.

Nutrient	Dietary treatment ^A						s.e.m.	P-value
Nutrient	1-FM	2-U30	3-U120	4-M2	5-M10	6-Auto	s.e.m.	P-value
Dry matter	913b	895c	899c	914b	910b	932a	1.50	0.000
Crude protein (N × 6.25)	897ab	911a	907ab	895b	895ab	902ab	2.43	0.031
Arginine	49.1	54.9	56.8	51.4	53.2	53.3	2.28	0.362
Alanine	17.5	20.5	20.7	18.9	18.0	18.1	1.17	0.415
Aspartic acid	47.5	53.6	56.2	48.5	52.4	51.3	2.95	0.437
Glutamic acid	129.0	151.5	155.6	136.4	144.2	146.9	7.58	0.295
Glycine	55.0	69.8	68.9	61.5	62.7	68.8	3.55	0.186
Histidine	8.1ab	8.3a	7.9ab	5.5c	5.5c	6.0abc	0.35	0.01
Isoleucine	32.6	35.9	37.9	34.0	34.4	35.5	1.76	0.437
Leucine	60.7	65.0	67.8	58.9	63.2	62.6	3.78	0.58
Lysine	19.8	21.5	22.4	17.7	17.8	19.1	0.88	0.064
Methionine	6.8	7.3	7.5	6.6	6.7	6.8	0.26	0.25
Phenylalanine	34.8	37.4	38.4	32.5	36.4	36.8	2.25	0.584
Proline	69.0	82.2	82.3	80.4	76.5	77.3	3.92	0.385
Serine	109.1	117.5	120.2	112.1	119.3	122.2	6.6	0.775
Threonine	35.7	39.1	39.8	36.3	36.7	37.5	1.71	0.544
Tyrosine	21.5	23.0	24.1	20.9	22.8	23.3	0.93	0.411
Valine	51.2	63.9	65.0	61.3	50.4	52.2	2.83	0.065
Total	785.5	890.9	909.4	820.0	841.4	862.8	38.28	0.345

Values in the same row with different letters are significantly different (at P = 0.05).

^A 1-FM (control untreated FM); 2-U30 (ultrasound 30 min); 3-U120 (ultrasound 120 min); 4-M2 (microwave 2 min); 5-M10 (microwave 10 min); 6-Auto (autoclave).

The AA profile of the six FM samples after physical treatment are shown in Table 4. There was no statistical difference between FM samples after treatment although it is worth noting that all physical treatments numerically increased total AA concentration of all AAs and this increase ranged from 4% to 12%. Leucine was the most abundant essential AA, whereas glutamic acid was the most abundant non-essential one.

Digestibility of FM after different physical treatments

Results of the effects of the physical treatments on amino acid digestibility are shown in Table 5. No statistical difference was found in amino acid digestibility among the six treatments (P > 0.05). Numerically, ultrasonic- or microwave-treated FMs had higher ileal amino acid digestibility in broilers than did untreated FM, but autoclaved FM had lower ileal amino acid digestibility than did untreated feather meal.

Table 5.Apparent ileal digestibility (%) of amino acids in feather meal subjected to different physical treatments and assayed in broilers.

Nutrient	Dietary treatment ^A						s.e.m.	P-value
Nutrient	1-FM	2-U30	3-U120	4-M2	5-M10	6-Auto	s.e.m.	P-value
Alanine	72.7	75.7	71.8	76.0	70.7	69.4	2.77	0.377
Arginine	74.4	75.0	72.0	76.7	72.4	70.6	2.79	0.557
Aspartic acid	39.2	40.7	38.1	45.4	39.8	37.0	5.26	0.844
Glutamic acid	60.0	64.0	59.4	64.8	59.9	58.1	3.75	0.533
Glycine	65.4	73.4	69.4	71.0	69.1	66.8	3.86	0.356
Histidine	71.7	67.7	62.4	63.3	60.2	56.1	4.32	0.326
Isoleucine	79.6	80.1	77.9	81.9	76.9	75.9	2.4	0.478
Leucine	76.0	74.1	71.8	75.9	72.1	69.9	2.73	0.754
Lysine	67.6	64.4	63.8	66.7	60.0	61.5	2.91	0.656
Methionine	61.6	62.8	59.1	63.6	58.9	57.7	2.89	0.659
Phenylalanine	79.0	76.9	74.9	77.9	77.4	72.7	2.56	0.755
Proline	56.1	63.7	57.2	64.8	58.1	56.0	3.74	0.193
Serine	66.6	67.8	63.9	70.0	66.1	64.9	3.46	0.629
Threonine	59.6	61.4	58.0	63.6	58.3	57.6	3.75	0.729
Tyrosine	71.4	70.3	68.4	73.1	69.6	67.3	2.98	0.772
Valine	73.4	78.5	75.6	79.9	72.2	70.5	2.43	0.076
Overall mean	64.5	66.8	65.0	66.3	65.8	62.2	3.43	0.749

^A 1-FM (control untreated FM); 2-U30 (ultrasound 30 min); 3-U120 (ultrasound 120 min); 4-M2 (microwave 2 min); 5-M10 (microwave 10 min); 6-Auto (autoclave).

Protease and probiotic supplementation and digestibility of feather meal

The digestibility coefficient of crude protein was increased following supplementation with both a protease and a probiotic (Table 6). The effect was significantly (P < 0.05) greater with the higher protease concentration of 600 mg/kg. The overall digestibility of amino acids was about 10% lower than for crude protein, but the average values were numerically improved in all experimental treatments (Table 6). Digestibility values for histidine were considered unreliable and have not been included for this experiment. The greatest increase in amino acid digestibility occurred following supplementation with RAP at 600 mg/kg, followed by supplementation with the probiotic, BioPlus 400. The increases in AA digestibility were minimal in diet 2 (200 mg/kg RPA). For individual amino acids, significant (P < 0.05) improvements were observed in the digestibility of arginine, isoleucine, phenylalanine, and valine. glutamic acid, leucine, lysine and serine all had notable (P < 0.10) increases in digestibility (Table 6).

Table 6.The effect of the protease and probiotic on apparent ileal protein and amino acid digestibility (%) of feather meal in broilers.

Nutrient	Dietary treatment				s.e.m.	P-value
Nutrient	1-Control	2-RAP (200 mg/kg)	3-RAP (600 mg/kg)	4-Bioplus 400 (1500 mg/kg)	s.e.m.	P-value
Crude protein	74.1b	77.5ab	80.5a	78.4ab	1.11	0.038
Alanine	69.5	70.7	75.0	71.1	1.75	0.154
Arginine	70.8b	72.2b	77.5a	74.9ab	1.00	0.009
Aspartic acid	43.7	42.9	48.4	39.2	3.18	0.133
Glutamic acid	61.6	61.7	67.9	62.7	1.85	0.069
Glycine	66.6	68.8	73.0	70.6	1.47	0.16
Isoleucine	74.6b	75.4b	81.6a	80.9a	0.91	0.006
Leucine	69.2	69.0	74.1	72.6	1.24	0.076
Lysine	70.5	68.5	71.4	65.3	1.51	0.097
Methionine	79.5	81.0	82.4	78.4	1.81	0.287
Phenylalanine	72.7b	75.1ab	79.9a	78.0ab	1.51	0.021
Proline	61.5	62.7	68.4	63.8	1.81	0.149
Serine	65.1	67.6	71.8	68.9	1.67	0.083
Threonine	60.1	61.6	65.1	61.1	1.55	0.232
Tyrosine	70.5	71.3	75.1	72.9	1.69	0.241
Valine	68.2ab	67.4b	74.1a	71.3ab	1.05	0.03
Overall mean	64.8	65.8	70.8	67.4	1.48	0.055

Values in the same row with different letters are significantly different (at P = 0.05).

RPA, Ronozyme® ProAct.

Discussion

The AA profiles of FMs determined in the present experiments were within the ranges reported previously (Papadopoulos et al. 1985; Papadopoulos et al. 1986; Han and Parsons 1991; Latshaw et al. 1994; Moritz and Latshaw 2001; Ravindran et al. 2005; Bandegan et al. 2010). Methionine and histidine had the lowest concentrations of essential AAs, whereas leucine and valine had the highest concentrations. No significant differences were observed among physically treated FMs in total AA concentrations and apparent ileal AA digestibility; demonstrating that AA profiles of FM were not affected by the physical treatments applied in these studies. This was a disappointing result because physical treatments are recognised as green processes because the use of toxic chemicals is avoided (Zoccola et al. 2012). It was unexpected because physical treatments including ultrasonic, microwave and autoclave treatments were thought to be practical methods that would improve the utilisation of FM protein. It may be that the hydrolysis of raw feathers to create FM leaves little scope for further improvement with additional physical processing. Nevertheless, a number of studies have shown that autoclaving (Papadopoulos et al. 1986), microwaving (Chen et al. 2015) and ultrasound (Qin et al. 2023) improve FM quality. However, the major difference between these studies and the current study is the starting material used. We used hydrolysed feathers or FM, whereas the other studies used raw feathers and focused on improving keratin solubility.

Both the protease and probiotic evaluated in Experiment 2 improved ileal AA digestibility of FM, but in both instances, this effect was observed when a dose that exceeded the commercially recommended dose was fed. The protease chosen for this study had been shown in vitro to outperform other commercial proteases in the degradation of feathers and hair (Navone and Speight 2018). Although not marketed as a keratinase, RAP has keratinolytic activity, especially when added to diet at a concentration of 600 mg/kg. However, Bertechini et al. (2020) found that RAP at the recommended commercial concentration of 200 mg/kg enhanced AA digestibility of FM for broilers when incorporated in a corn–soybean basal diet and fed for 7 days. Although the two studies are not directly comparable because many factors can influence both AA digestibility and the protease value in poultry diets (Cowieson and Roos 2013; Romero and Plumstead 2013), they demonstrate the keratinolytic activity of RPA. Other studies (Angel et al. 2011; Fru-Nji et al. 2011; Saleh et al. 2020b) using the recommended dose, achieved satisfactory improvements (4–8%) in protein digestibility, but the diets fed did not include a refractory protein such as keratin found in FM.

There are a number of possible mechanisms through which probiotics may enhance bird performance (see Shini and Bryden 2022). It was our hypothesis in this study that the Bacillus licheniformis component of BioPlus 440 produces a keratinase and that ‘super dosing’ with the probiotic at 1500 mg/kg or three times the recommended dose would allow the expression of the keratinolytic activity of B. licheniformis. The results of the study support the hypothesis. Moreover, Mazotto et al. (2011) reported that FM was a great substrate for induction of the activity of a keratinase and peptidase in B. subtilis 1273. Such a mechanism may have contributed to the results observed in Experiment 2, following the addition of BioPlus 400. Furthermore, the proportion of Bacillus licheniformis and Bacillus subtilis in broiler diets is also a factor that influences their effect on broilers. Yang et al. (2017) indicated that 6.6 × 10⁵:3.3 × 10⁵ was the optimal proportion for Partridge Shank chicks to significantly improve the small intestine morphology. However, the optimal ratio for Ross 308 broilers has not been reported and this might be an important aspect in the effect of BioPlus 400 in the current experiment.

It is likely that the addition of protease or probiotic in the current study would improve nutrient digestibility of diets by modifying the morphology of the small intestine of broilers. Probiotics have been shown to improve the small intestinal morphology of broilers, including proteome changes and increases to villous length and width, crypt depth and epithelial thickness (Luo et al. 2014; Shini et al. 2021). This would increase nutrient utilisation because of an increased intestinal surface area for absorption (Awad et al. 2008). Kamel et al. (2015) added RPA at a rate of 200 ppm in corn–soybean meal diets for broilers and observed a significant increase in villus:crypt ratio. The ability of both feed additives to maintain or improve gut integrity would contribute to the results observed.

In conclusion, the quest for technologies to improve the utilisation of FM continues. The current studies indicated that there is scope for further improvement in the nutritive value of FM for broilers. Both the protease and Bacillus sp. probiotic demonstrated an ability to improve the protein digestibility of FM as a protein source for broilers. How this was achieved was unclear and further delineation of the modes of action of both the protease and probiotic would facilitate their strategic application.

Data availability

Data may be made available upon reasonable request to the corresponding author.

Conflicts of interest

WLB is a member of the Editorial Board of Animal Production Science but was not involved in the review and editorial process for this paper. The authors have no further conflicts of interest to declare.

Declaration of funding

This study was supported by the Australian Government Department of Agriculture, Water and the Environment as part of its Rural R&D for Profit program and the School of Agriculture and Food Sustainability, the University of Queensland.

Acknowledgements

We appreciate the assistance of postgraduate students who helped with the conduct of the bioassays and Dr G. Cai is thanked for assistance with amino acid analysis.

References

Angel CR, Saylor W, Vieira SL, Ward N (2011) Effects of a monocomponent protease on performance and protein utilization in 7 to 22 day-old broiler chickens. Poultry Science 90, 2281-2286.
| Crossref | Google Scholar | PubMed |

Awad W, Ghareeb K, Böhm J (2008) Intestinal structure and function of broiler chickens on diets supplemented with a synbiotic containing Enterococcus faecium and oligosaccharides. International Journal of Molecular Sciences 9, 2205-2216.
| Crossref | Google Scholar | PubMed |

Bai S, Wu A, Ding X, Lei Y, Bai J, Zhang K, Chio J (2013) Effects of probiotic-supplemented diets on growth performance and intestinal immune characteristics of broiler chickens. Poultry Science 92, 663-670.
| Crossref | Google Scholar | PubMed |

Bajagai YS, Yeoh YK, Li X, Zhang D, Dennis PG, Ouwerkerk D, Dart PJ, Klieve AV, Bryden WL (2023) Enhanced meat chicken productivity in response to the probiotic Bacillus amyloliquefaciens H57 is associated with the enrichment of microbial amino acid and vitamin biosynthesis pathways. Journal of Applied Microbiology 134, lxad085.
| Crossref | Google Scholar |

Bandegan A, Kiarie E, Payne RL, Crow GH, Guenter W, Nyachoti CM (2010) Standardized ileal amino acid digestibility in dry-extruded expelled soybean meal, extruded canola seed-pea, feather meal, and poultry by-product meal for broiler chickens. Poultry Science 89, 2626-2633.
| Crossref | Google Scholar | PubMed |

Bedford MR, Morgan AJ (1996) The use of enzymes in poultry diets. World’s Poultry Science Journal 52, 61-68.
| Crossref | Google Scholar |

Bertechini AG, de Carvalho JCC, Carvalho AC, Dalolio FS, Sorbara JOB (2020) Amino acid digestibility coefficient values of animal protein meals with dietary protease for broiler chickens. Translational Animal Science 4, txaa187.
| Crossref | Google Scholar |

Brandelli A (2008) Bacterial keratinases: useful enzymes for bioprocessing agroindustrial wastes and beyond. Food and Bioprocess Technology 1, 105-116.
| Crossref | Google Scholar |

Brandelli A, Daroit DJ, Riffel A (2010) Biochemical features of microbial keratinases and their production and applications. Applied Microbiology and Biotechnology 85, 1735-1750.
| Crossref | Google Scholar | PubMed |

Cai G, Moffitt K, Navone L, Zhang Z, Robins K, Speight R (2022) Valorisation of keratin waste: controlled pretreatment enhances enzymatic production of antioxidant peptides. Journal of Environmental Management 301, 113945.
| Crossref | Google Scholar | PubMed |

Chen L, Wang N, Sun D, Li L (2014) Microwave-assisted acid hydrolysis of proteins combined with peptide fractionation and mass spectrometry analysis for characterizing protein terminal sequences. Journal of Proteomics 100, 68-78.
| Crossref | Google Scholar | PubMed |

Chen J, Ding S, Ji Y, Ding J, Yang X, Zou M, Li Z (2015) Microwave-enhanced hydrolysis of poultry feather to produce amino acid. Chemical Engineering and Processing: Process Intensification 87, 104-109.
| Crossref | Google Scholar |

Cherry JP, Young CT, Shewfelt AL (1975) Characterization of protein isolates from keratinous material of poultry feathers. Journal of Food Science 40, 331-335.
| Crossref | Google Scholar |

Cowieson AJ, Roos FF (2013) Bioefficacy of a mono-component protease in the diets of pigs and poultry: a meta-analysis of effect on ileal amino acid digestibility. Journal of Applied Animal Nutrition 2, e13.
| Crossref | Google Scholar |

Cowieson AJ, Roos FF (2016) Toward optimal value creation through the application of exogenous mono-component protease in the diets of non-ruminants. Animal Feed Science and Technology 221, 331-340.
| Crossref | Google Scholar |

Dai L, Wang Y, Liu Y, Ruan R (2020) Microwave-assisted pyrolysis of formic acid pretreated bamboo sawdust for bio-oil production. Environmental Research 182, 108988.
| Crossref | Google Scholar | PubMed |

Daroit DJ, Corrêa APF, Segalin J, Brandelli A (2010) Characterization of a keratinolytic protease produced by the feather-degrading Amazonian bacterium Bacillus sp. P45. Biocatalysis and Biotransformation 28, 370-379.
| Crossref | Google Scholar |

El Boushy AR, van der Poel AFB, Walraven OED (1990) Feather meal – a biological waste: its processing and utilization as a feedstuff for poultry. Biological Wastes 32, 39-74.
| Crossref | Google Scholar |

Fru-Nji F, Kluenter A-M, Fischer M, Pontoppidan K (2011) A feed serine protease improves broiler performance and increases protein and energy digestibility. The Journal of Poultry Science 48, 239-246.
| Crossref | Google Scholar |

Glitsø V, Pontoppidan K, Knap I, Ward N (2012) Development of a feed protease. Industrial Biotechnology 8, 172-175.
| Crossref | Google Scholar |

Grazziotin A, Pimentel FA, de Jong EV, Brandelli A (2006) Nutritional improvement of feather protein by treatment with microbial keratinase. Animal Feed Science and Technology 126, 135-144.
| Crossref | Google Scholar |

Han Y, Parsons C (1991) Protein and amino acid quality of feather meals. Poultry Science 70, 812-822.
| Crossref | Google Scholar |

Kaewtapee C, Burbach K, Tomforde G, Hartinger T, Camarinha-Silva A, Heinritz S, Seifert J, Wiltafsky M, Mosenthin R, Rosenfelder-Kuon P (2017) Effect of Bacillus subtilis and Bacillus licheniformis supplementation in diets with low- and high-protein content on ileal crude protein and amino acid digestibility and intestinal microbiota composition of growing pigs. Journal of Animal Science and Biotechnology 8, 37.
| Crossref | Google Scholar |

Kamel NF, Naela, Ragaa M, El-Banna R, Mohamed F (2015) Effects of a monocomponent protease on performance parameters and protein digestibility in broiler chickens. Agriculture and Agricultural Science Procedia 6, 216-225.
| Crossref | Google Scholar |

Kreplak L, Doucet J, Dumas P, Briki F (2004) New aspects of the α-helix to β-sheet transition in stretched hard α-keratin fibers. Biophysical Journal 87, 640-647.
| Crossref | Google Scholar | PubMed |

Latshaw JD, Musharaf N, Retrum R (1994) Processing of feather meal to maximize its nutritional value for poultry. Animal Feed Science and Technology 47, 179-188.
| Crossref | Google Scholar |

Lee YS, Phang L-Y, Ahmad SA, Ooi PT (2016) Microwave–alkali treatment of chicken feathers for protein hydrolysate production. Waste and Biomass Valorization 7, 1147-1157.
| Crossref | Google Scholar |

Li Q (2019) Progress in microbial degradation of feather waste. Frontiers in Microbiology 10, 2717.
| Crossref | Google Scholar | PubMed |

Li X, Higgins TJV, Bryden WL (2006) Biological response of broiler chickens fed peas (Pisum sativum) expressing the bean (Phaseolus vulgaris L.) α-amylase inhibitor transgene. Journal of the Science of Food and Agriculture 86, 1900-1907.
| Crossref | Google Scholar |

Li J-F, Wei F, Dong X-Y, Guo L-L, Yuan G-Y, Huang F-H, Jiang M-L, Zhao Y-D, Li G-M, Chen H (2010) Microwave-assisted approach for the rapid enzymatic digestion of rapeseed meal. Food Science and Biotechnology 19, 463-469.
| Crossref | Google Scholar |

Lindberg D, Kristoffersen KA, Wubshet SG, Hunnes LMG, Dalsnes M, Dankel KR, Høst V, Afseth NK (2021) Exploring effects of protease choice and protease combinations in enzymatic protein hydrolysis of poultry by-products. Molecules 26, 5280.
| Crossref | Google Scholar | PubMed |

Liu X, Yan H, Le L, Xu C, Yin C, Zhang K, Wang P, Hu J (2012) Growth performance and meat quality of broiler chickens supplemented with Bacillus licheniformis in drinking water. Asian-Australasian Journal of Animal Sciences 25, 682-689.
| Crossref | Google Scholar | PubMed |

Luo J, Zheng A, Meng K, Chang W, Bai Y, Li K, Cai H, Liu G, Yao B (2014) Proteome changes in the intestinal mucosa of broiler (Gallus gallus) activated by probiotic Enterococcus faecium. Journal of Proteomics 91, 226-241.
| Crossref | Google Scholar |

Luong VB, Payne CG (1977) Hydrolysed feather protein as a source of amino acids for laying hens. British Poultry Science 8, 523-526.
| Crossref | Google Scholar |

MacAlpine R, Payne CG (1977) Hydrolysed feather protein as a source of amino acids for broilers. British Poultry Science 18, 265-273.
| Crossref | Google Scholar |

Mazotto AM, Coelho RRR, Cedrola SML, de Lima MF, Couri S, Paraguai de Souza E, Vermelho AB (2011) Keratinase production by three Bacillus spp. using feather meal and whole feather as substrate in a submerged fermentation. Enzyme Research 2011, 523780.
| Crossref | Google Scholar |

Moritz JS, Latshaw JD (2001) Indicators of nutritional value of hydrolyzed feather meal. Poultry Science 80, 79-86.
| Crossref | Google Scholar | PubMed |

Navone L, Speight R (2018) Understanding the dynamics of keratin weakening and hydrolysis by proteases. PLoS ONE 13, e0202608.
| Crossref | Google Scholar | PubMed |

NHMRC (2013) Australian code for the care and use of animals for scientific purposes. 8th Edn, National Health and Medical Research Council, Canberra, ACT. Australia.

Onifade AA, Al-Sane NA, Al-Musallam AA, Al-Zarban S (1998) A review: potentials for biotechnological applications of keratin-degrading microorganisms and their enzymes for nutritional improvement of feathers and other keratins as livestock feed resources. Bioresource Technology 66, 1-11.
| Crossref | Google Scholar |

Papadopoulos MC, El Boushy AR, Ketelaars EH (1985) Effect of different processing conditions on amino acid digestibility of feather meal determined by chicken assay. Poultry Science 64, 1729-1741.
| Crossref | Google Scholar |

Papadopoulos MC, El Boushy AR, Roodbeen AE, Ketelaars EH (1986) Effects of processing time and moisture content on amino acid composition and nitrogen characteristics of feather meal. Animal Feed Science and Technology 14, 279-290.
| Crossref | Google Scholar |

Parry DA, North A (1998) Hard alpha-keratin intermediate filament chains: substructure of the N-and C-terminal domains and the predicted structure and function of the C-terminal domains of type I and type II chains. Journal of Structural Biology 122, 67-75.
| Crossref | Google Scholar | PubMed |

Patist A, Bates D (2008) Ultrasonic innovations in the food industry: from the laboratory to commercial production. Innovative Food Science & Emerging Technologies 9, 147-154.
| Crossref | Google Scholar |

Polin D (1992) Feathers, feather meal and other poultry by-products. In ‘Advances in meat research, Vol. 8, inedible meat by-products’. (Eds AM Pearson, TR Dutson) pp. 177–198. (Elsevier Inc.: New York, NY, USA)

Qin X, Yang C, Guo Y, Liu J, Bitter JH, Scott EL, Zhang C (2023) Effect of ultrasound on keratin valorization from chicken feather waste: process optimization and keratin characterization. Ultrasonics Sonochemistry 93, 106297.
| Crossref | Google Scholar |

Ravindran V (2013) Feed enzymes: The science, practice, and metabolic realities. Journal of Applied Poultry Research 22, 628-636.
| Crossref | Google Scholar |

Ravindran V, Hew LI, Ravindran G, Bryden WL (1999) A comparison of ileal digesta and excreta analysis for the determination of amino acid digestibility in food ingredients for poultry. British Poultry Science 40, 266-274.
| Crossref | Google Scholar | PubMed |

Ravindran V, Hew LI, Ravindran G, Bryden WL (2005) Apparent ileal digestibility of amino acids in dietary ingredients for broiler chickens. Animal Science 81, 85-97.
| Crossref | Google Scholar |

Rodríguez-Clavel IS, Paredes-Carrera SP, Flores-Valle SO, Paz-García EJ, Sánchez-Ochoa JC, Pérez-Gutiérrez RM (2019) Effect of microwave or ultrasound irradiation in the extraction from feather keratin. Journal of Chemistry 2019, 1326063.
| Crossref | Google Scholar |

Romero L, Plumstead P (2013) Bio-efficacy of feed proteases in poultry and their interaction with other feed enzymes. Proceedings of the Australian Poultry Science Symposium 24, 23-30.
| Google Scholar |

Saleh AA, Amber K, Mohammed AA (2020a) Dietary supplementation with avilamycin and Lactobacillus acidophilus effects growth performance and the expression of growth-related genes in broilers. Animal Production Science 60, 1704-1710.
| Crossref | Google Scholar |

Saleh AA, Dawood MM, Badawi NA, Ebeid TA, Amber KA, Azzam MM (2020b) Effect of supplemental serine-protease from Bacillus licheniformis on growth performance and physiological change of broiler chickens. Journal of Applied Animal Research 48, 86-92.
| Crossref | Google Scholar |

Shini S, Bryden WL (2022) Probiotics and gut health: linking gut homeostasis and poultry productivity. Animal Production Science 62, 1090-1112.
| Crossref | Google Scholar |

Shini S, Acland RC, Bryden WL (2021) Avian intestinal ultrastructure changes provide insight into the pathogenesis of enteric infections and probiotic mode of action. Scientific Reports 11, 167.
| Crossref | Google Scholar | PubMed |

Sun X, Ohanenye IC, Ahmed T, Udenigwe CC (2020) Microwave treatment increased protein digestibility of pigeon pea (Cajanus cajan) flour: elucidation of underlying mechanisms. Food Chemistry 329, 127196.
| Crossref | Google Scholar | PubMed |

Šabatková J, Kumprecht I, Zobač P, Suchý P, Čermák B (2008) The probiotic BioPlus 2B as an alternative to antibiotics in diets for broiler chickens. Acta Veterinaria Brno 77, 569-574.
| Crossref | Google Scholar |

Sweeney RA (1989) Generic combustion method for determination of crude protein in feeds: Collaborative study. Journal of Association of Official Analytical Chemists 72, 770-774.
| Crossref | Google Scholar |

Yang J, Kun Q, Dong W, Zhang W, Wu Y, Xu Y (2017) Effects of different proportions of two Bacillus sp. on the growth performance, small intestinal morphology, caecal microbiota and plasma biochemical profile of Chinese Huainan Partridge Shank chickens. Journal of Integrative Agriculture 16, 1383-1392.
| Crossref | Google Scholar |

Zaghari M, Sarani P, Hajati H (2020) Comparison of two probiotic preparations on growth performance, intestinal microbiota, nutrient digestibility and cytokine gene expression in broiler chickens. Journal of Applied Animal Research 48, 166-175.
| Crossref | Google Scholar |

Zheng M, Bai Y, Sun Y, An J, Chen Q, Zhang T (2023) Effects of different proteases on protein digestion in vitro and in vivo and growth performance of broilers fed corn–soybean meal diets. Animals 13, 1746.
| Crossref | Google Scholar | PubMed |

Zoccola M, Aluigi A, Patrucco A, Vineis C, Forlini F, Locatelli P, Sacchi MC, Tonin C (2012) Microwave-assisted chemical-free hydrolysis of wool keratin. Textile Research Journal 82, 2006-2018.
| Crossref | Google Scholar |