Background:Algae are widely recognized for their high oil content and for exponentially accumulating biomass with particular potential to provide single cell protein for human consumption or animal feed.It is believe...Background:Algae are widely recognized for their high oil content and for exponentially accumulating biomass with particular potential to provide single cell protein for human consumption or animal feed.It is believed that along with biodiesel from algae,the high protein de-oiled algal residue may become an alternative feed supplement option in the future.This study was conducted to investigate de-oiled algal residue obtained from the common Chlorella species,Thalassiosira weissflogii,Selenarstrum capricornutum,Scenedesmus sp.,and Scenedesmus dimorphus for assessment as potential feed supplements for ruminants by comparing with soybean(Glycine max) meal and alfalfa(Medicago sativa) hay.Results:With the exception of T.weissflogii,algal residue had higher concentrations of Cu,Zn,and Mn and lower concentration of Ca,Mg,and K than soybean meal and alfalfa hay.The algal residue CP(crude protein)concentrations ranged from 140 to 445 g/kg DM and varied among the de-oiled residues.In vitro rumen fermentation gas accumulation curves indicated that algal biomass degradation potential was less than that of soybean meal or alfalfa hay by up to 41.7%.The gas production curve,interpreted with a dual pool logistic model,confirmed that the fraction sizes for fast fermenting and slow fermenting of de-oiled algal residues were smaller than those in soybean meal and alfalfa hay,and the fermenting rate of the fractions was also low.Conclusions:Inferior in vitro rumen gas accumulation from the five de-oiled algal residues suggests that these algal byproducts are less degradable in the rumen.展开更多
Effects of some methodological factors on in vitro measures of gas production(GP, mL/g DM), CH4production(mL/g DM) and proportion(% CH4 on total GP) were investigated by meta-analysis. These factors were conside...Effects of some methodological factors on in vitro measures of gas production(GP, mL/g DM), CH4production(mL/g DM) and proportion(% CH4 on total GP) were investigated by meta-analysis. These factors were considered:pressure in the GP equipment(0 = constant; 1 = increasing), incubation time(0 = 24; 1 = ≥ 48 h), time of rumen fluid collection(0 = before feeding; 1 = after feeding of donor animals), donor species of rumen fluid(0 = sheep; 1 =bovine), presence of N in the buffer solution(0 = presence; 1 = absence), and ratio between amount of buffered rumen fluid and feed sample(BRF/FS; 0 = ≤ 130 mL/g DM; 1 = 130–140 mL/g DM; 2 = ≥ 140 mL/g DM). The NDF content of feed sample incubated(NDF) was considered as a continuous variable. From an initial database of 105 papers, 58 were discarded because one of the above-mentioned factors was not stated. After discarding 17 papers,the final dataset comprised 30 papers(339 observations). A preliminary mixed model analysis was carried out on experimental data considering the study as random factor. Variables adjusted for study effect were analyzed using a backward stepwise analysis including the above-mentioned variables. The analysis showed that the extension of incubation time and reduction of NDF increased GP and CH4 values. Values of GP and CH4 also increased when rumen fluid was collected after feeding compared to before feeding(+26.4 and +9.0 mL/g DM, for GP and CH4),from bovine compared to sheep(+32.8 and +5.2 mL/g DM, for GP and CH4), and when the buffer solution did not contain N(+24.7 and +6.7 mL/g DM for GP and CH4). The increase of BRF/FS ratio enhanced GP and CH4production(+7.7 and +3.3 mL/g DM per each class of increase, respectively). In vitro techniques for measuring GP and CH4 production are mostly used as screening methods, thus a full standardization of such techniques is not feasible. However, a greater harmonization of analytical procedures(i.e., a reduction in the number of available protocols) would be useful to facilitate comparison between results of different experiments.展开更多
Alfalfa (Medicago sativa) is difficult to ensile successfully because of the low content of moisture and water-soluble carbohydrates (WSC) in fresh alfalfa and the high buffering capacity in fresh alfalfa. Here, w...Alfalfa (Medicago sativa) is difficult to ensile successfully because of the low content of moisture and water-soluble carbohydrates (WSC) in fresh alfalfa and the high buffering capacity in fresh alfalfa. Here, we conducted a study to evaluate the effects of three lactic acid bacteria (LAB) inoculants (Lactobacillus case/, lactobacillus plantarum, and Pediococcus pentosaceus) on silage quality, in sitE/ruminal degradability, and in vitro fermentation of alfalfa silage. The first cut of alfalfa was wilted, chopped, and randomly divided into four groups: the control (CON) and control mixed with three separate LAB inoculants (106 cfu g-1). Simmental steers with a body weight of (452±18) kg and with installed rumen fistulas were prepared for in situ degradation and for in vitro gas production. LAB inoculants had a lower (P〈0.05) content of butyric acid than the CON group. Among them, the L. casei inoculated silage had a higher (P〈0.05) content of water-soluble carbohydrate (WSC) and a lower (P〈0.05) NH3-H content. The effective degradation (ED) of crude protein in LAB inoculation decreased (P〈0.05), while the ED of acid detergent fiber increased (P〈0.05) in situ fermentation. The alfalfa silage with LAB inoculants produced more carbon dioxide (P〈0.05). The NH3-H content of mixed incubation fluid in L. casei inoculated silage was lower (P〈0.05) compared with other groups. Therefore, this study showed that LAB inoculants could improve both ensiling quality and degradation. In particular, the L. casei inoculations exhibited better performance by limiting proteolysis during ensiling.展开更多
Excessive mining and utilization fossil fuels has led to drastic environmental consequences,which will contribute to global warming and cause further climate change with severe consequences for the human population.Th...Excessive mining and utilization fossil fuels has led to drastic environmental consequences,which will contribute to global warming and cause further climate change with severe consequences for the human population.The magnitude of these challenges requires several approaches to develop sustainable alternatives for chemicals and fuels production.In this context,biological processes,mainly microbial fermentation,have gained particular interest.For example,autotrophic gas-fermenting acetogenic bacteria are capable of converting CO,CO_(2) and H_(2) into biomass and multiple metabolites through Wood-Ljungdahl pathway,which can be exploited for large-scale fermentation processes to sustainably produce bulk biochemicals and biofuels(e.g.acetate and ethanol)from syngas.Clostridium autoethanogenum is one representative of these chemoautotrophic bacteria and considered as the model for the gas fermentation.Recently,the development of synthetic biology toolbox for this strain has enabled us to study and genetically improve their metabolic capability in gas fermentation.In this review,we will summarize the recent progress involved in the understanding of physiological mechanism and strain engineering for C.autoethanogenum,and provide our perspectives on the future development about the basic biology and engineering biology of this strain.展开更多
基金supported by Louisiana Board of Regents Research grant
文摘Background:Algae are widely recognized for their high oil content and for exponentially accumulating biomass with particular potential to provide single cell protein for human consumption or animal feed.It is believed that along with biodiesel from algae,the high protein de-oiled algal residue may become an alternative feed supplement option in the future.This study was conducted to investigate de-oiled algal residue obtained from the common Chlorella species,Thalassiosira weissflogii,Selenarstrum capricornutum,Scenedesmus sp.,and Scenedesmus dimorphus for assessment as potential feed supplements for ruminants by comparing with soybean(Glycine max) meal and alfalfa(Medicago sativa) hay.Results:With the exception of T.weissflogii,algal residue had higher concentrations of Cu,Zn,and Mn and lower concentration of Ca,Mg,and K than soybean meal and alfalfa hay.The algal residue CP(crude protein)concentrations ranged from 140 to 445 g/kg DM and varied among the de-oiled residues.In vitro rumen fermentation gas accumulation curves indicated that algal biomass degradation potential was less than that of soybean meal or alfalfa hay by up to 41.7%.The gas production curve,interpreted with a dual pool logistic model,confirmed that the fraction sizes for fast fermenting and slow fermenting of de-oiled algal residues were smaller than those in soybean meal and alfalfa hay,and the fermenting rate of the fractions was also low.Conclusions:Inferior in vitro rumen gas accumulation from the five de-oiled algal residues suggests that these algal byproducts are less degradable in the rumen.
基金financed by the project “ARCHAEA- Feeding strategies to reduce methane emissions from dairy cows,”Veneto Region Rural Development Programme (RDP) 2007–2013 “Progetto di Ateneo cod. CPDA 155250”, University of Padova, Italy
文摘Effects of some methodological factors on in vitro measures of gas production(GP, mL/g DM), CH4production(mL/g DM) and proportion(% CH4 on total GP) were investigated by meta-analysis. These factors were considered:pressure in the GP equipment(0 = constant; 1 = increasing), incubation time(0 = 24; 1 = ≥ 48 h), time of rumen fluid collection(0 = before feeding; 1 = after feeding of donor animals), donor species of rumen fluid(0 = sheep; 1 =bovine), presence of N in the buffer solution(0 = presence; 1 = absence), and ratio between amount of buffered rumen fluid and feed sample(BRF/FS; 0 = ≤ 130 mL/g DM; 1 = 130–140 mL/g DM; 2 = ≥ 140 mL/g DM). The NDF content of feed sample incubated(NDF) was considered as a continuous variable. From an initial database of 105 papers, 58 were discarded because one of the above-mentioned factors was not stated. After discarding 17 papers,the final dataset comprised 30 papers(339 observations). A preliminary mixed model analysis was carried out on experimental data considering the study as random factor. Variables adjusted for study effect were analyzed using a backward stepwise analysis including the above-mentioned variables. The analysis showed that the extension of incubation time and reduction of NDF increased GP and CH4 values. Values of GP and CH4 also increased when rumen fluid was collected after feeding compared to before feeding(+26.4 and +9.0 mL/g DM, for GP and CH4),from bovine compared to sheep(+32.8 and +5.2 mL/g DM, for GP and CH4), and when the buffer solution did not contain N(+24.7 and +6.7 mL/g DM for GP and CH4). The increase of BRF/FS ratio enhanced GP and CH4production(+7.7 and +3.3 mL/g DM per each class of increase, respectively). In vitro techniques for measuring GP and CH4 production are mostly used as screening methods, thus a full standardization of such techniques is not feasible. However, a greater harmonization of analytical procedures(i.e., a reduction in the number of available protocols) would be useful to facilitate comparison between results of different experiments.
基金funded by the projects of the National Public Welfare Industry (Agriculture) R&D Program,China (201303061)the China Agricultural Research System (CARS-39)
文摘Alfalfa (Medicago sativa) is difficult to ensile successfully because of the low content of moisture and water-soluble carbohydrates (WSC) in fresh alfalfa and the high buffering capacity in fresh alfalfa. Here, we conducted a study to evaluate the effects of three lactic acid bacteria (LAB) inoculants (Lactobacillus case/, lactobacillus plantarum, and Pediococcus pentosaceus) on silage quality, in sitE/ruminal degradability, and in vitro fermentation of alfalfa silage. The first cut of alfalfa was wilted, chopped, and randomly divided into four groups: the control (CON) and control mixed with three separate LAB inoculants (106 cfu g-1). Simmental steers with a body weight of (452±18) kg and with installed rumen fistulas were prepared for in situ degradation and for in vitro gas production. LAB inoculants had a lower (P〈0.05) content of butyric acid than the CON group. Among them, the L. casei inoculated silage had a higher (P〈0.05) content of water-soluble carbohydrate (WSC) and a lower (P〈0.05) NH3-H content. The effective degradation (ED) of crude protein in LAB inoculation decreased (P〈0.05), while the ED of acid detergent fiber increased (P〈0.05) in situ fermentation. The alfalfa silage with LAB inoculants produced more carbon dioxide (P〈0.05). The NH3-H content of mixed incubation fluid in L. casei inoculated silage was lower (P〈0.05) compared with other groups. Therefore, this study showed that LAB inoculants could improve both ensiling quality and degradation. In particular, the L. casei inoculations exhibited better performance by limiting proteolysis during ensiling.
基金supported by the Shenzhen Science and Technology Program(Grant No.JCYJ20210324101014036).
文摘Excessive mining and utilization fossil fuels has led to drastic environmental consequences,which will contribute to global warming and cause further climate change with severe consequences for the human population.The magnitude of these challenges requires several approaches to develop sustainable alternatives for chemicals and fuels production.In this context,biological processes,mainly microbial fermentation,have gained particular interest.For example,autotrophic gas-fermenting acetogenic bacteria are capable of converting CO,CO_(2) and H_(2) into biomass and multiple metabolites through Wood-Ljungdahl pathway,which can be exploited for large-scale fermentation processes to sustainably produce bulk biochemicals and biofuels(e.g.acetate and ethanol)from syngas.Clostridium autoethanogenum is one representative of these chemoautotrophic bacteria and considered as the model for the gas fermentation.Recently,the development of synthetic biology toolbox for this strain has enabled us to study and genetically improve their metabolic capability in gas fermentation.In this review,we will summarize the recent progress involved in the understanding of physiological mechanism and strain engineering for C.autoethanogenum,and provide our perspectives on the future development about the basic biology and engineering biology of this strain.
