1 n Earth and establish a solid foundation for
biotechnological adaptation of a whole-cell approach to
2 pproach, combined with metagenomics data and
biotechnological advances, will enhance CO2 sequestratio
3 uct of different fish species as a potential
biotechnological alternative for the industry.
4 Although
biotechnological alternatives, including RNA interferenc
5 clinical, environmental, pharmaceutical, or
biotechnological analysis being potential areas for futu
6 ier to the exploitation of cyanobacteria for
biotechnological and biomedical applications.
7 n of artificial ComRS systems for a range of
biotechnological and biomedical applications.
8 ubility is often an essential requirement in
biotechnological and biomedical applications.
9 s or endogenous inputs have a broad range of
biotechnological and biomedical applications.
10 tation-and-memory gene circuits for numerous
biotechnological and biomedical applications.
11 reservoir of bioactive compounds of immense
biotechnological and biomedical potential.
12 ic biology modification and for a variety of
biotechnological and biophysical applications.
13 s have become an indispensable tool for many
biotechnological and clinical applications.
14 The taxonomic status,
biotechnological and ecological potential of several Mic
15 ractions are context-dependent in performing
biotechnological and ecosystem processes remains largely
16 IF-8-rGO is a promising nanozyme for various
biotechnological and environmental applications.
17 s and composites preparation for biomedical,
biotechnological and environmental applications.
18 r a range of applications in the biomedical,
biotechnological and environmental areas.
19 novo design of minimalistic biocatalysts for
biotechnological and industrial applications.
20 Insights gained could be exploited for
biotechnological and medical applications of fungi.
21 novel metabolites in organisms relevant for
biotechnological and medical applications remains a chal
22 d-AQuA enable it to be suitable for multiple
biotechnological and medical applications.
23 N- and O-linked glycosylation processing for
biotechnological and medically relevant cells together w
24 erious implications in a range of areas from
biotechnological and pharmaceutical applications to medi
25 , environmental adaptation and for potential
biotechnological and pharmaceutical applications.
26 the catalytic conversion of plant oils, via
biotechnological and purely chemical approaches, likewis
27 orly understood and are of much interest for
biotechnological and research applications, as well as o
28 the potential to accelerate a wide array of
biotechnological and therapeutic applications of the CRI
29 These advances pave the way toward
biotechnological and therapeutic applications.
30 mplex synthetic functionalities in cells for
biotechnological and therapeutic applications.
31 tically alter or destroy target proteins for
biotechnological and therapeutic applications.Proteases
32 ials and improved aggregation inhibitors for
biotechnological and therapeutic purposes.
33 is a need to investigate this phenomenon for
biotechnological and therapeutic purposes.
34 dies are high value therapeutic, diagnostic,
biotechnological,
and research tools.
35 ular cloning is a cornerstone of biomedical,
biotechnological,
and synthetic biology research.
36 This system's
biotechnological application in drug screening was succe
37 y new strains and enzymes with potential for
biotechnological application.
38 study this rare process and develop it as a
biotechnological application.
39 ortance of starch biosynthesis for yield and
biotechnological application.
40 linking of proteins and peptides in food and
biotechnological applications (e.g. to improve the textu
41 marine vibrios as fast urea hydrolyzers for
biotechnological applications aiming at nutrient recover
42 s exploited as a bacteriocide in medical and
biotechnological applications and also by the mammalian
43 assembly pathway will provide tools for new
biotechnological applications and inform the design of t
44 differences in mAG composition could advance
biotechnological applications and lead to new antimicrob
45 regarding indole and its derivatives, their
biotechnological applications and their role in prokaryo
46 lignocellulose degradation with relevance to
biotechnological applications as biofuel production, the
47 neered nucleases in genome editing and other
biotechnological applications as well as spontaneous and
48 on identified a suite of strains for further
biotechnological applications e.g. Dunaliella polymorpha
49 powerful tool to determine the most suitable
biotechnological applications for a given alga type and
50 luorescent DNA dyes are broadly used in many
biotechnological applications for detecting and imaging
51 onses to nutrient starvation and on possible
biotechnological applications for green algae.
52 ith tools to evade CRISPR-Cas12a and support
biotechnological applications for which multiple-turnove
53 valuable information for the development of
biotechnological applications from brown algae biomass.
54 of new orthogonal regulatory components for
biotechnological applications including gene functional
55 cteria would be particularly well suited for
biotechnological applications involving nitrogen recover
56 an potentially broaden the existing scope of
biotechnological applications of Cas9 nucleases and may
57 We also discuss the potential
biotechnological applications of chloroplast genomes.
58 ensively researched, the myriad of potential
biotechnological applications of methanotrophic bacteria
59 his process is essential if the wide-ranging
biotechnological applications of methanotrophs are to be
60 e on alginate lyases and facilitating future
biotechnological applications of PL36 alginate lyases.
61 a lot of enzymes are not accessible for the
biotechnological applications or industrial use.
62 es and could benefit engineering efforts for
biotechnological applications ranging from production of
63 n fundamental biological processes(1) and in
biotechnological applications such as DNA nanopore seque
64 has attracted interest due to its potential
biotechnological applications, and as a model for algal
65 thogenic and non-pathogenic environments, in
biotechnological applications, and beyond the microbial
66 ug carrier than L6 for biomedical as well as
biotechnological applications, and that the function of
67 cal processes, have important industrial and
biotechnological applications, are important drug target
68 ap source of phenolic compounds suitable for
biotechnological applications, as a strategy for sustain
69 In most yeast-driven
biotechnological applications, biomass is separated from
70 It is an attractive target for
biotechnological applications, but metabolic engineering
71 For different metabolic engineering and
biotechnological applications, however, an enzyme that c
72 Many chemical and
biotechnological applications, however, involve only sma
73 nded DNA genome, which, among other multiple
biotechnological applications, is used as an expression
74 is widely used in a number of biological and
biotechnological applications, mainly because of its eff
75 first step toward developing strategies for
biotechnological applications, such as improvement of ni
76 of heterologous protein production with many
biotechnological applications, such as in pharmaceutical
77 es have been extensively studied, either for
biotechnological applications, such as phage display, or
78 Moreover, they are used in biomedical and
biotechnological applications, such as targeted delivery
79 This process could be exploited for
biotechnological applications, such as waste treatment a
80 of high relevance for various industrial and
biotechnological applications, the comprehensive identif
81 genetically manipulating these organisms for
biotechnological applications, the enzymes themselves ar
82 beta-(1->3)-glucans and their wide range of
biotechnological applications, the identification of enz
83 obial manipulation approaches and innovative
biotechnological applications.
84 ts development and evolution, as well as its
biotechnological applications.
85 tegies that, in turn, could be exploited for
biotechnological applications.
86 to improve performance of Chlorella spp. for
biotechnological applications.
87 t have a variety of diagnostic, clinical and
biotechnological applications.
88 designing redox-active proteins for diverse
biotechnological applications.
89 ovides exciting possibilities for industrial/
biotechnological applications.
90 the whole stem of T. media has potential for
biotechnological applications.
91 y and activity, these results have potential
biotechnological applications.
92 nsion of the genetic code and other possible
biotechnological applications.
93 the engineering of oleaginous microalgae for
biotechnological applications.
94 luable natural products with a wide range of
biotechnological applications.
95 aracterized CAZymes for future deployment in
biotechnological applications.
96 use of rennin in cheese production and other
biotechnological applications.
97 ng ssDNA, an important material for numerous
biotechnological applications.
98 biomimetic nanocompartments for medical and
biotechnological applications.
99 utants should be considered to design robust
biotechnological applications.
100 ein-protein interactions, for biosensing and
biotechnological applications.
101 e of novel genes and pathways with potential
biotechnological applications.
102 n disease-causing amyloids and amyloid-based
biotechnological applications.
103 rations in their physiological scenarios and
biotechnological applications.
104 e is an ubiquitous enzyme which has enormous
biotechnological applications.
105 ures for a variety of biological studies and
biotechnological applications.
106 mutants for future biophysical analyses and
biotechnological applications.
107 and could be used in various industrial and
biotechnological applications.
108 avidin (SA) and biotin is widely utilized in
biotechnological applications.
109 .7 +/- 17.6-fold, which is adequate for many
biotechnological applications.
110 s identifying new enzymes for biomedical and
biotechnological applications.
111 l properties is important for scientific and
biotechnological applications.
112 in-mediated protein splicing has found broad
biotechnological applications.
113 opment of robust proteins for biomedical and
biotechnological applications.
114 ted fundamental biological understanding and
biotechnological applications.
115 nuclease activities, which may be useful for
biotechnological applications.
116 ld be engineered for additional clinical and
biotechnological applications.
117 ng films for enzyme immobilisation and other
biotechnological applications.
118 communities can also open up new avenues for
biotechnological applications.
119 nform manipulation for synthetic biology and
biotechnological applications.
120 ld form the foundation of multiple potential
biotechnological applications.
121 of using prokaryotic photosynthetic cells in
biotechnological applications.
122 thetic prokaryotes, are attractive hosts for
biotechnological applications.
123 d guide the design of collagen scaffolds for
biotechnological applications.
124 uld potentially be exploited for fine-tuning
biotechnological applications.
125 on Cas9's conformation and suggest possible
biotechnological applications.
126 ly be useful tools for synthetic biology and
biotechnological applications.
127 icrocompartments using synthetic biology for
biotechnological applications.
128 h food spoilage and are also used in various
biotechnological applications.
129 s as well as engineer complex phenotypes for
biotechnological applications.
130 plications for both biological processes and
biotechnological applications.
131 mes, as well as different pharmaceutical and
biotechnological applications.
132 d provides potential targets for breeding or
biotechnological applications.
133 l-secreted proteins is essential for various
biotechnological applications.
134 ology despite their huge potential regarding
biotechnological applications.
135 tant catalysts for O(2) reduction in various
biotechnological applications.
136 ised interest in oxidases and oxygenases for
biotechnological applications.
137 the potential for widespread biomedical and
biotechnological applications.
138 ion, opening new avenues for therapeutic and
biotechnological applications.
139 We also illustrate the use of STTM RNA in a
biotechnological approach for enhancing quantitative dis
140 vel genes that will be useful candidates for
biotechnological approaches aimed at altering seed size
141 ackground and justification for breeding and
biotechnological approaches for improving O3 tolerance i
142 Biotechnological approaches have been evaluated in conne
143 r the development of new clinically relevant
biotechnological approaches suitable for deciphering the
144 sceptibility via marker-assisted breeding or
biotechnological approaches.
145 for its applications across a wide range of
biotechnological areas.
146 useful for applications in molecular and/or
biotechnological breeding.
147 ioproduction and explores its potential as a
biotechnological chassis.
148 we propose a bioderivatization strategy for
biotechnological chemicals production, defined as purpos
149 plications including biological, biomedical,
biotechnological,
clinical and medical diagnostics, envi
150 on lipid membranes in a broad biological and
biotechnological context.
151 The development of advanced
biotechnological control strategies opens a new era of e
152 s that limit growth and yield, and may allow
biotechnological crop improvement.
153 In the
biotechnological desulfurization process under haloalkal
154 ary regimens and might prove useful also for
biotechnological developments of new strains and for und
155 stacle that prevents them being used in many
biotechnological devices.
156 paves the way to the development of powerful
biotechnological devices.
157 Thus, many
biotechnological,
diagnostic and therapeutic opportuniti
158 nized genome editing across a broad range of
biotechnological endeavors.
159 yotic chassis for a suite of fundamental and
biotechnological endeavours.
160 tudies lay the foundation for biomedical and
biotechnological engineering applications that could tak
161 Despite advances in the
biotechnological exploitation of select systems, multipl
162 f side-stream (FSS) with great potential for
biotechnological exploitation.
163 r acidification of microorganisms in various
biotechnological fermentation processes is on demand.
164 s in chemical, biochemical, biophysical, and
biotechnological fields.
165 at has substantial practical applications in
biotechnological fields.
166 l design of glycan structures with optimized
biotechnological functions.
167 ons and establish MtrC as a new benchmark in
biotechnological H2O2 reduction with scope for applicati
168 with important ecological, evolutionary, and
biotechnological implications.
169 tionship between DNA and solvent, with clear
biotechnological implications.
170 coagulation and has important biomedical and
biotechnological implications.
171 ungi in constructing biosensors broadens the
biotechnological importance of these microorganisms.
172 However, despite the biological and
biotechnological importance of this macromolecule, its t
173 nscriptome analysis to the rodent species of
biotechnological importance, for which the development o
174 ucose tolerant enzymes is of biochemical and
biotechnological importance.
175 s far from commensurate with its medical and
biotechnological importance.
176 ynthesis, providing a basis for the targeted
biotechnological improvement of crops.
177 viridis for dissection of complex traits and
biotechnological improvement of panicoid crops.
178 vaginatum, illustrating a possible path for
biotechnological improvement of salt-sensitive Panicoid
179 study is of value for both conventional and
biotechnological improvement programs.
180 phite as an alternative phosphorus source in
biotechnological,
industrial and agricultural applicatio
181 biology that laid the foundations for modern
biotechnological industries.
182 gal proteases potential alternatives for the
biotechnological industry.
183 decade has seen bacteria at the forefront of
biotechnological innovation, with applications including
184 the future, combining genomic selection with
biotechnological innovations, such as genome editing and
185 bacterial aging), while opening the door to
biotechnological innovations.
186 ses effectively degrade cellulose and are of
biotechnological interest because they can convert ligno
187 roalgae have reemerged as organisms of prime
biotechnological interest due to their ability to synthe
188 soluble sugars, making them a biocatalyst of
biotechnological interest for use in the nascent lignoce
189 Despite the significant
biotechnological interest in producing value-added compo
190 (VP) is a high redox-potential peroxidase of
biotechnological interest that is able to oxidize phenol
191 The latter are of
biotechnological interest, as Acrs can serve as off swit
192 y, plant legumains have become of particular
biotechnological interest, e.g. for the synthesis of cyc
193 ycetes that, apart from being of genetic and
biotechnological interest, is also reported to be a plan
194 lly versatile Actinobacteria of considerable
biotechnological interest.
195 heir folding and assembly is of considerable
biotechnological interest.
196 n of analytes of environmental, clinical, or
biotechnological interest.
197 sessing the impact of either breeding and/or
biotechnological interventions aimed at increasing grain
198 of T. canis to support future biological and
biotechnological investigations.
199 s) with wide-ranging applications in diverse
biotechnological niches.
200 ne stereoisomers in samples of biological or
biotechnological origin demands for dedicated high effic
201 ns for their genetic manipulation, and offer
biotechnological pathways to improve yield.
202 M. hentscheli and could pave the way toward
biotechnological peloruside production.
203 ere termed co-factor balance, will influence
biotechnological performance.
204 l, astringency and colour and supports a new
biotechnological perspective for red winemakers.
205 tiva) and wheat (Triticum aestivum), opening
biotechnological perspectives in crop plants.
206 es is fundamental when studying cellular and
biotechnological phenomena.
207 s the characterization and evaluation of the
biotechnological potential of a cysteine protease purifi
208 All results support the
biotechnological potential of CpCP3 as an alternative en
209 In this study, the
biotechnological potential of CsF3H was evaluated by gen
210 The therapeutic and
biotechnological potential of phages and their lytic enz
211 Given the
biotechnological potential of the isovaleryl-CoA/pivalyl
212 ps yeast as an efficient tool to harness the
biotechnological potential of the numerous sequencing da
213 up of photosynthetic microalgae, have a high
biotechnological potential that has not been fully explo
214 Finally, we emphasize the emerging
biotechnological potential use of PRRs to improve broad-
215 odactyla helianthus with high biomedical and
biotechnological potential, toward elastase-like enzymes
216 tic activity and stability, or enhance their
biotechnological potential.
217 very of a new versatile esterase with a high
biotechnological potential.
218 elds, has distinctive genomic, adaptive, and
biotechnological potential.
219 ion of insulin represent serious medical and
biotechnological problems.
220 with low pH and high metal concentration in
biotechnological processes for treatment of metal-laden
221 The development of reliable, mixed-culture
biotechnological processes hinges on understanding how m
222 Programmes for improving
biotechnological processes might therefore give greater
223 However, many
biotechnological processes, as well as natural habitats,
224 nce of cooperative interactions in microbial
biotechnological processes, discuss their mechanistic or
225 efficiency of the platforms used in various
biotechnological processes.
226 to a broad range of biological specimens and
biotechnological processes.
227 iomass is crucial to develop nature-inspired
biotechnological processes.
228 industries, as well as in nanotechnology and
biotechnological processes.
229 aboratory routines to increasing the pace of
biotechnological production cycles.
230 Scalable
biotechnological production for four industrially releva
231 d a case is put forward for the necessity of
biotechnological production methods such as plant cell c
232 have developed an effective process for the
biotechnological production of alpha-ketoisocaproate tha
233 dings lay the foundation for the sustainable
biotechnological production of astins independent from a
234 trates renders them ideal candidates for the
biotechnological production of commodity chemicals.
235 hus attracting considerable interest for the
biotechnological production of fuels, environmental reme
236 for improvement of strawberry flavor and the
biotechnological production of HDMF-glucoside.
237 g innate immunity with metabolism and in the
biotechnological production of itaconic acid by Aspergil
238 ctivity, and 3) improving CAD efficiency for
biotechnological production of itaconic acid.
239 This is within the range of
biotechnological production of other peptides in plants.
240 , ranging from environmental stresses to the
biotechnological production of small molecules and prote
241 Biotechnological production of these peptides in plants
242 anaerobic conditions is being developed as a
biotechnological production platform.
243 ts are suffering from wildcrafting, and thus
biotechnological production processes of their natural p
244 ar to induce bnAbs demanding their expensive
biotechnological production.
245 become a valuable starting material for many
biotechnological products through manipulation of its N-
246 y human diseases and with the degradation of
biotechnological products.
247 specific strains of these communities offers
biotechnological promise in therapeutic discovery and in
248 Here we investigate the
biotechnological properties of the mutant SsoPox-W263I,
249 sibility of mining seaweed genomes for their
biotechnological prowess.
250 scale synthesis of complex carbohydrates for
biotechnological purposes.
251 to promote or suppress host interactions for
biotechnological purposes.
252 function and pinpoint potential pathways of
biotechnological relevance for future cell engineering.
253 s assembly of large repetitive proteins with
biotechnological relevance.
254 basic research on oleogenic microalgae with
biotechnological relevance.
255 sion, our data open up new possibilities for
biotechnological research in Chlamydomonas.
256 integration for biological, biomedical, and
biotechnological research is less known.
257 NA synthesis is in demand for biological and
biotechnological research.
258 of 42 free intracellular metabolites within
biotechnological samples, while tandem mass isotopomer i
259 for high-throughput robotics, and convenient
biotechnological scale-up.
260 of applications in material, biological, and
biotechnological sciences.
261 ition to the analytical chemistry toolbox of
biotechnological starch utilization.
262 Protein design advancements have led to
biotechnological strategies based on more stable and mor
263 protein storage, which have implications for
biotechnological strategies directed at improving oilsee
264 Biotechnological strategies for improving O3 tolerance a
265 and will ultimately allow the validation of
biotechnological strategies to produce crops with enhanc
266 We compare estimated theoretical yields of
biotechnological substrates and of chemicals of environm
267 rs play also important roles in context with
biotechnological surfaces, for instance, when they are t
268 nd antimicrobial compound, starting with its
biotechnological synthesis and ending with its antimicro
269 iotic-abiotic interfaces in both natural and
biotechnological systems.
270 ications in a large number of biological and
biotechnological systems.
271 ative protein source for food production and
biotechnological systems.
272 A potential
biotechnological target for improving the production of
273 Furthermore, SvBAHD05 is a promising
biotechnological target to engineer crops for improved b
274 biosynthetic pathway, represents a promising
biotechnological target to reduce lignin levels and to i
275 fic trends that can be used to determine new
biotechnological targets for crop improvement.
276 novel approaches might use these proteins as
biotechnological targets for disease control, and contri
277 c adaptive immune systems, have emerged as a
biotechnological tool and therapeutic.
278 COase is an important
biotechnological tool for clinical diagnostics and produ
279 esca L. plants, providing a very interesting
biotechnological tool for potential food applications.
280 results, our approach represents a promising
biotechnological tool for reducing of biomass recalcitra
281 ous substrates make chymotrypsin useful as a
biotechnological tool in food processing.
282 me and suggests A3A's potential utility as a
biotechnological tool to discriminate between cytosine m
283 rate tolerance of PCY1 can be exploited as a
biotechnological tool to generate structurally diverse a
284 further work in the development of CPMV as a
biotechnological tool.
285 microbial design and as a microbiological or
biotechnological tool.
286 has enabled further expansion of CRISPR-Cas
biotechnological toolkits, with wide-ranging application
287 have uncovered a deep reservoir of potential
biotechnological tools beyond the well-characterized Typ
288 These findings will provide useful
biotechnological tools to improve stress tolerance while
289 However, new
biotechnological tools--specifically CRISPR-based techno
290 ysiological roles and are also very powerful
biotechnological tools.
291 gy and evolution, and the development of new
biotechnological tools.
292 ve low substrate specificity, impeding their
biotechnological use as enzymes that do not cross-react
293 pic of considerable interest, with potential
biotechnological use implicit in the discovery of promis
294 LPAT and DGAT activities and demonstrate the
biotechnological use of these enzymes to generate 10:0-r
295 Despite the high interest in
biotechnological uses of this species, little is known a
296 A microbe's ecological niche and
biotechnological utility are determined by its specific
297 ial yeast strains could greatly expand their
biotechnological utility.
298 cellulose and chitin, and are of interest in
biotechnological utilization of these abundant biomateri
299 ations in the measurement, manipulation, and
biotechnological utilization of unmodified RNAs in intac
300 ific activity and open new avenues for their
biotechnological utilization.