«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶½­ËÕÅ©Òµ¿Æѧ¡·[ISSN:1002-1302/CN:32-1214/S]

¾í:

µÚ42¾í

ÆÚÊý:

2014Äê07ÆÚ

Ò³Âë:

387-391

À¸Ä¿:

ÖÊÁ¿°²È«Óë¼ì²â·ÖÎö

³ö°æÈÕÆÚ:

2014-07-25

ÎÄÕÂÐÅÏ¢/Info

Title:

Research progress on xylanase production by micro-organisms

×÷Õß:

Û§ÎÀÄǹ;  ÕÅÀ¼Ó¢²;  ºÎ½¡¹;  ºØÇÛ¹

1.ÄϾ©Å©Òµ´óѧÉúÃü¿ÆѧѧԺ/Å©Òµ²¿Å©Òµ»·¾³Î¢ÉúÎ﹤³ÌÖص㿪·ÅʵÑéÊÒ£¬½­ËÕÄϾ© 210095£» 2.½­Î÷Ê¡ÄÏ¿µÊеÚһСѧ£¬½­Î÷ÄÏ¿µ 341400

Author(s):

Qie Weina; et al

¹Ø¼ü´Ê:

ľ¾ÛÌÇø; ¹¦ÄÜ·ÖÀà; ×÷ÓûúÀí; ¸ß²ú¾úÖê; ¹¤Òµ»¯Ó¦ÓÃ

Keywords:

-

·ÖÀàºÅ:

TS201.2+5£»Q556+.2

DOI:

-

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

ľ¾ÛÌÇøÊÇÉúÎï¼¼ÊõÁìÓòµÄÑо¿Èȵ㡣½éÉÜÁËľ¾ÛÌÇøµÄ·ÖÀà¡¢×÷ÓûúÀí¡¢¸ß²ú¾úÖêµÄÖÖÀ༰»ñµÃ¡¢¹¤ÒµÓ¦Óõȣ¬ÒÔÆÚΪָµ¼Ä¾¾ÛÌÇø¹¤Òµ»¯Éú²úÓëÓ¦Óý¨Á¢»ù´¡¡£

Abstract:

-

²Î¿¼ÎÄÏ×/References:

£Û1£ÝÕÅÍõÕÕ£¬ÍõÑÇÈ㣬ÑîºÆÃÈ. ËÇÓÃľ¾ÛÌÇøµÄÑо¿½øÕ¹£ÛJ£Ý. ËÇÁϹã½Ç£¬2005(15)£º27-28£¬30.
£Û2£ÝUffen R L. Xylan degradation£ºa glimpse at microbial diversity£ÛJ£Ý. Journal of Industrial Microbiology and Biotechnology£¬1997£¬19(1)£º1-6.
£Û3£ÝPolizeli M L£¬Rizzatti A C£¬Monti R£¬et al. Xylanases from fungi£ºproperties and industrial applications£ÛJ£Ý. Applied Microbiology and Biotechnology£¬2005£¬67(5)£º577-591.
£Û4£ÝÁõÁÁ࣬ÇØÌì²Ô£¬µÔ¼Ì£¬µÈ. F/10¼°G/11ľ¾ÛÌÇø¼Ò×åÃÜÂë×ÓÆ«ºÃÐÔ·ÖÎö£ÛJ£Ý. ºÓÄÏÅ©Òµ´óѧѧ±¨£¬2008£¬42(2)£º223-227.
£Û5£ÝÁõÁÁΰ£¬ÕŸïУ¬ºØÌúÃ÷£¬µÈ. F/10ºÍG/11ľ¾ÛÌÇø¼Ò×åµÄ²»Í¬ÈÈÎȶ¨ÐÔ»úÖÆ£ÛJ£Ý. ÎÞÎýÇṤ´óѧѧ±¨£¬2005£¬24(1)£º52-58.
£Û6£ÝPoon D K£¬Withers S G£¬McIntosh L P. Direct demonstration of the flexibility of the glycosylated proline-threonine linker in the Cellulomonas fimi xylanase cex through NMR spectroscopic analysis£ÛJ£Ý. Journal of Biological Chemistry£¬2007£¬282(3)£º2091-2100.
£Û7£ÝVrzheshch P V. Steady-state kinetics of bifunctional enzymes. Taking into account kinetic hierarchy of fast and slow catalytic cycles in a generalized model£ÛJ£Ý. Biochemistry-Moscow£¬2007£¬72(9)£º936-943.
£Û8£ÝGilbert H J£¬Hazelwood G P. Bacterial celluloses and xylanases£ÛJ£Ý. Journal of General Microbiology£¬1993£¬139£º187-194.
£Û9£ÝJames C L£¬Viola R E. Production and characterization of bifunctional enzymes. Domain swapping to produce new bifunctional enzymes in the aspartate pathway£ÛJ£Ý. Biochemistry£¬2002£¬41(11)£º3720-3725.
£Û10£Ý¹ú´ºÑÞ£¬»ÆÎÀ±ó£¬ÖìÒÙ£¬µÈ. ËÇÓÃľ¾ÛÌÇøµÄ½á¹¹Ìص㼰ÔÚÉú²úÖеÄÓ¦ÓãÛJ£Ý. ËÇÁϹ¤Òµ£¬2007£¬28(22)£º9-11.
£Û11£ÝÉۼ̺£.΢ÉúÎïľ¾ÛÌÇøÑо¿½øÕ¹£ÛJ£Ý. ËÇÁϹ¤Òµ£¬2009£¬30(14)£º18-20.
£Û12£ÝKhandeparker R£¬Numan M T. Bifunctional xylanases and their potential use in biotechnology£ÛJ£Ý. Journal of Industrial Microbiology and Biotechnology£¬2008£¬35(7)£º635-644.
£Û13£ÝBray M R£¬Clarke A J. Essential carboxy groups in xylanase A£ÛJ£Ý. Biochemical Journal£¬1990£¬270(1)£º91-96.
£Û14£Ý³ÂºéÕÂ.ÏËάËØÉúÎï¼¼Êõ£ÛM£Ý. 2°æ.±±¾©£º»¯Ñ§¹¤Òµ³ö°æÉ磬2011£º285-288.
£Û15£ÝS¢‰rensen H. Xylanase in the soil and the rumen£ÛJ£Ý. Nature£¬1955£¬176(4471)£º74.
£Û16£ÝÔøÓî³É£¬ÕÅÊ÷Õþ. º£ÔæÇúù²úÉúµÄÌÇÜÕøÀà£ÛJ£Ý. ΢ÉúÎïѧͨ±¨£¬1987(3)£º111-114.
£Û17£ÝFang H Y£¬Chang S M£¬Hsieh M C£¬et al. Production£¬optimization growth conditions and properties of the xylanase from Aspergillus carneus M34£ÛJ£Ý. Journal of Molecular Catalysis B - Enzymatic£¬2007£¬49(1/2/3/4)£º36-42.
£Û18£ÝYang S Q£¬Yan Q J£¬Jiang Z Q£¬et al. High-level of xylanase production by the thermophilic Paecilomyces themophila J18 on wheat straw in solid-state fermentation£ÛJ£Ý. Bioresource Technology£¬2006£¬97(15)£º1794-1800.
£Û19£ÝSenthilkumar S R£¬Ashokkumar B£¬Chandra Raj K£¬et al. Optimization of medium composition for alkali-stable xylanase production by Aspergillus fischeri Fxn 1 in solid-state fermentation using central composite rotary design£ÛJ£Ý. Bioresource Technology£¬2005£¬96(12)£º1380-1386.
£Û20£ÝShah A R£¬Madamwar D. Xylanase production by a newly isolated Aspergillus foetidus strain and its characterization£ÛJ£Ý. Process Biochemistry£¬2005£¬40(5)£º1763-1771.
£Û21£ÝSingh M P£¬Pandey A K£¬Vishwakarma S K£¬et al. Extracellular xylanase production by Pleurotus species on lignocellulosic wastes under in vivo condition using novel pretreatment£ÛJ£Ý. Cellular and Molecular Biology£¬2012£¬58(1)£º170-173.
£Û22£Ý Battan B£¬Sharma J£¬Dhiman S S£¬et al. Enhanced production of cellulase-free thermostable xylanase by Bacillus pumilus ASH and its potential application in paper industry£ÛJ£Ý. Enzyme and Microbial Technology£¬2007£¬41(6/7)£º733-739.
£Û23£ÝMohana S£¬Shah A£¬Divecha J£¬et al. Xylanase production by Burkholderia sp. DMAX strain under solid state fermentation using distillery spent wash£ÛJ£Ý. Bioresource Technology£¬2008£¬99(16)£º7553-7564.
£Û24£ÝNinawe S£¬Kuhad R C. Use of xylan-rich cost effective agro-residues in the production of xylanase by Streptomyces cyaneus SN32£ÛJ£Ý. Journal of Applied Microbiology£¬2005£¬99(5)£º1141-1148.
£Û25£ÝGomes J£¬Gomes I£¬Steiner W. Thermolabile xylanase of the Antarctic yeast Cryptococcus adeliae£ºproduction and properties£ÛJ£Ý. Extremophiles£¬2000£¬4(4)£º227-235.
£Û26£ÝÐí°²£¬Ò¦½¨Ãú£¬ÓàÔöÁÁ. Àë×Ó×¢Èë¸ÄÁ¼Î¬ÉúËØC¶þ²½·¢½Í»ìºÏ¾úÑо¿(¢ñ)2-ͪ»ù-L-¹ÅÁúËá¸ß²ú¾úϵIPPM-1028µÄÑ¡Óý£ÛJ£Ý. ¹¤ÒµÎ¢ÉúÎ1998£¬28(4)£º21-24.
£Û27£ÝLi S C£¬Yao J M£¬Yu Z L. Studies on mutation breeding of high-yielding xylanase strains by low-energy ion beam implantation£ÛJ£Ý. Plasma Science and Technology£¬2007£¬9(2)£º248-251.
£Û28£Ý°üâùºì£¬Áõΰ·á£¬¶­Ö¾Ñï. ÄͼîÐÔľ¾ÛÌÇøÔÚ¶ÌСѿæ߸˾úÖиßЧ·ÖÃÚ±í´ïµÄÑо¿£ÛJ£Ý. ÖйúʳƷѧ±¨£¬2008£¬8(5)£º37-43.
£Û29£ÝNaber J E£¬Schepman A M J£¬R¢‰rsch A. The binding of deoxyribonucleases of Escherichia coli to deoxyribonucleic acid immobilized in agarose£ÛJ£Ý. Biochim Biophys Acta£¬1966£¬114(2)£º326-337.
£Û30£ÝBaumann M J£¬Murphy L£¬Lei N£¬et al. Advantages of isothermal titration calorimetry for xylanase kinetics in comparison to chemical-reducing-end assays£ÛJ£Ý. Analytical Biochemistry£¬2011£¬410(1)£º19-26.
£Û31£ÝMohn W W£¬Stewart G R. Bacterial metabolism of chlorinated dehydroabietic acids occurring in pulp and paper mill effluents£ÛJ£Ý. Applied and Environmental Microbiology£¬1997£¬63(8)£º3014-3020.
£Û32£ÝHaki G D£¬Rakshit S K. Developments in industrially important thermostable enzymes£ºa review£ÛJ£Ý. Bioresource Technology£¬2003£¬89(1)£º17-34.
£Û33£ÝÄô¹úÐË£¬Íõ¿¡Àö£¬Ã÷ºì. ľ¾ÛÌÇøµÄÓ¦ÓÃÏÖ×´ÓëÑз¢Èȵã£ÛJ£Ý. ¹¤ÒµÎ¢ÉúÎ2008£¬38(1)£º53-59.
£Û34£ÝUysal H£¬Bilgicli N£¬Elg¨¹n A£¬et al. Effect of dietary fibre and xylanase enzyme addition on the selected properties of wire-cut cookies£ÛJ£Ý. Journal of Food Engineering£¬2007£¬78(3)£º1074-1078.

ÏàËÆÎÄÏ×/References:

[1]³£¹ðÓ¢,Íõ¿¡Áá,ÐìÑÇά,µÈ.ľ¾ÛÌÇøxynB»ùÒòÐòÁзÖÎö¼°±í´ïÔØÌå¹¹½¨[J].½­ËÕÅ©Òµ¿Æѧ,2013,41(10):31.
¡¡Chang Guiying,et al.Sequence analysis and expression vector construction of xylanase xynB gene[J].Jiangsu Agricultural Sciences,2013,41(07):31.
[2]Û§ÎÀÄÇ,ÕÅÀ¼Ó¢,ºÎ½¡,µÈ.1ÖêËÇÓÃľ¾ÛÌÇø²úÉú¾úµÄ·ÖÀë¡¢¼ø¶¨¡¢·¢½Í¡¢Ã¸Ñ§ÐÔÖʼ°Ó¦ÓÃ[J].½­ËÕÅ©Òµ¿Æѧ,2014,42(10):196.
¡¡Qie Weina,et al.Isolation£¬identification£¬fermentation£¬enzymatic properties£¬ and application of an xylanase-producing strain for feed[J].Jiangsu Agricultural Sciences,2014,42(07):196.
[3]ÕÔÁªÕý,лռÁá,ÕÔÅó.Ò»ÖÖеÄÁ­µ¶¾úQ7-31ľ¾ÛÌÇøXyn9µÄ·ÖÀë´¿»¯¼ø¶¨¼°Ã¸Ñ§ÌØÐÔ[J].½­ËÕÅ©Òµ¿Æѧ,2015,43(05):42.
¡¡Zhao Liamzheng,et al.Purification£¬identification and enzymatic characteristics of a new xylanase Xyn9 from Fusarium sp. Q7-31[J].Jiangsu Agricultural Sciences,2015,43(07):42.
[4]ÍõÈñÀö,ÁõÃô½Ü,ѦҵÃô.¶à¹¦ÄÜÈÚºÏø»ùÒòLinkerµÄÓÅ»¯¼°±í´ï[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(04):31.
¡¡Wang Ruili,et al.Optimization and expression of multifunctional fusion enzyme gene linker[J].Jiangsu Agricultural Sciences,2016,44(07):31.
[5]ËÎÁ¢Á¢,¶Ù±¦Çì,ÕÅÑÇéª,µÈ.ľ¾ÛÌÇø»ùÒòµÄ¿Ë¡Óë±í´ï[J].½­ËÕÅ©Òµ¿Æѧ,2018,46(10):43.
¡¡Song Lili,et al.Cloning and expression of xylanase gene[J].Jiangsu Agricultural Sciences,2018,46(07):43.
[6]Í¿·ã,ÕÔΪÃñ,²Ü¾²,µÈ.ľ¾ÛÌÇø»ùÒò(XynB)³¦µÀÌØÒì±í´ïÔØÌåµÄ¹¹½¨¼°¼ø¶¨[J].½­ËÕÅ©Òµ¿Æѧ,2020,48(11):53.
¡¡Tu Feng,et al.Construction and identification of intestine specific expression vector of XynB gene[J].Jiangsu Agricultural Sciences,2020,48(07):53.

±¸×¢/Memo

±¸×¢/Memo:

ÊÕ¸åÈÕÆÚ£º2013-10-22
×÷Õß¼ò½é£ºÛ§ÎÀÄÇ(1986¡ª)£¬Å®£¬ºÓ±±Ê¯¼ÒׯÈË£¬Ë¶Ê¿Ñо¿Éú£¬´ÓÊ»·¾³Î¢ÉúÎïÓë»·¾³¹¤³ÌÑо¿¡£E-mail£ºwoniubeibao@gmail.com¡£
ͨÐÅ×÷ÕߣººØÇÛ£¬½²Ê¦£¬Ö÷Òª´ÓÊ»·¾³Î¢ÉúÎïÓë»·¾³¹¤³ÌÑо¿¡£E-mail£ºqhe@njau.edu.cn¡£

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2014-07-25