- Editorial Board
- Journal
- Preprinting Policy
- 个人中心
- 退出登录
浏览全部资源
扫码关注微信
- Editorial Board
- The 2nd EB
- The 1st EB
- Journal
- Latest Issue
- Archive
- Online First
- Preprinting Policy
- Preprinting Policy
- Data Policy
Green biomanufacturing of ceramide sphingolipids
- Synthetic Biology Journal Vol. 6, Issue 2, Pages: 422-444(2025)
- 作者机构:
1.江南大学生物工程学院, 糖化学与生物技术教育部重点实验室,江苏 无锡 214112
2.江南大学未来食品科学中心,江苏 无锡 214112
- 作者简介:
- 基金信息:
DOI:10.12211/2096-8280.2024-059
CLC: Q819Received:01 August 2024,
Revised:2024-10-11,
Published:30 April 2025
- 稿件说明:
移动端阅览
鲁锦畅, 武耀康, 吕雪芹, 刘龙, 陈坚, 刘延峰. 神经酰胺类鞘脂的绿色生物制造[J]. 合成生物学, 2025, 6(2): 422-444
LU Jinchang, WU Yaokang, LV Xueqin, LIU Long, CHEN Jian, LIU Yanfeng. Green biomanufacturing of ceramide sphingolipids[J]. Synthetic Biology Journal, 2025, 6(2): 422-444
鲁锦畅, 武耀康, 吕雪芹, 刘龙, 陈坚, 刘延峰. 神经酰胺类鞘脂的绿色生物制造[J]. 合成生物学, 2025, 6(2): 422-444 DOI: 10.12211/2096-8280.2024-059.
LU Jinchang, WU Yaokang, LV Xueqin, LIU Long, CHEN Jian, LIU Yanfeng. Green biomanufacturing of ceramide sphingolipids[J]. Synthetic Biology Journal, 2025, 6(2): 422-444 DOI: 10.12211/2096-8280.2024-059.
摘要
神经酰胺是一种存在于所有真核生物中的多功能生物活性物质,在细胞信号转导、细胞增殖、分化、凋亡和免疫调节中发挥着重要作用。神经酰胺天然存在于皮肤角质层中,起着支持肌肤屏障、保持水分、抗氧化衰老、抗菌抗炎等作用。因此,神经酰胺及其衍生物在化妆品、生物医药、功能食品等领域具有广阔的市场前景。神经酰胺构型存在多个立体中心,化学从头合成难度大,已知市售的天然或类神经酰胺化合物主要是通过传统天然提取法及生物化学相结合的半合成法获得。近年来,利用微生物合成神经酰胺等鞘脂类化合物已有报道,但从头合成效率还处于较低水平,如何实现细胞工厂高效生产神经酰胺具有重大意义。本文从神经酰胺的生理功能和应用出发,系统地综述了神经酰胺类物质的生理效应及功能;阐述了神经酰胺的天然提取方法、神经酰胺及其前体化合物的化学合成方法;并从鞘脂合成途径及关键酶出发介绍,引出途径调控与优化、产物的运输储存与分泌、关键酶的挖掘与表达等改造策略;最后,从神经酰胺合成面临的聚集毒性、高效运输分泌、数字化改造催化元件、基因调控靶点的拓展等方面进行了展望。合成生物学和生物技术的持续进步有助于扩大微生物细胞工厂的生产能力,实现神经酰胺等鞘脂类化合物的可持续绿色生物制造。
Abstract
Ceramide
a fundamental bioactive molecule found ubiquitously in eukaryotic organisms
exerts profound regulatory effect on ce
llular physiology
encompassing critical roles in signaling cascades
cellular proliferation
differentiation
and apoptosis
as well as immunomodulation. In dermatology
ceramides play an indispensable role as constituents of the stratum corneum
the outermost layer of the skin
where they are crucial for maintaining the integrity of the epidermal barrier
regulating moisture retention
combating oxidative stress linked to aging
and exhibiting notable antimicrobial and anti-inflammatory properties. The multifaceted biological functions of ceramides underscore their extensive applications in various industries
including cosmetics
biomedicine
functional food
and animal nutrition
highlighting their significant market potential and therapeutic value. The chemical synthesis of ceramides poses substantial challenges due to the intricate stereochemistry involved
necessitating precise control over synthetic pathways. As a result
current commercial sources predominantly rely on semi-synthetic methods that integrate traditional natural extraction techniques with biochemical transformations of sphingolipid precursors to achieve targeted ceramide structures. Recent advancements in synthetic biology have explored microbial systems for the production of sphingolipids
including ceramides
offering promising avenues for scalable and sustainable synthesis. However
optimizing
de novo
synthesis pathways and their efficiency in microbial cell factories remains a primary research focus. Strategies aimed at enhancing ceramide yield and purity through metabolic engineering and pathway optimization are pivotal for advancing industrial applications. This paper provides a systematic review of the physiological effectiveness and function of ceramides
encompassing their physiological roles and various applications. It begins with an overview of ceramide extraction methods
including both natural extraction techniques and chemical synthesis approaches for ceramides and their precursor compounds. Subsequently
the
review addresses the sphingolipid synthesis pathways and their associated key enzymes
detailing strategies for pathway regulation and optimization
as well as the aspects of product transport
storage
and secretion. Additionally
it explores the identification and expression of key enzymes. The paper concludes by examining future directions in the field
such as addressing aggregation toxicity in ceramide synthesis
enhancing transport and secretion mechanisms
advancing digital modifications of catalytic elements
and expanding gene regulatory target exploration. By synthesizing current knowledge and highlighting avenues for innovation
this review aims to catalyze further research effort toward achieving efficient ceramide production. Ultimately
optimizing ceramide synthesis has the potential to unlock its full potential in various sectors
contributing to its advancement in skincare
therapeutics
and functional materials. The integration of microbial systems is particularly promising for expanding production capabilities while addressing sustainability concerns in ceramide manufacturing. Continued advancements in synthetic biology and biotechnology are expected to revolutionize the landscape of ceramide applications
paving the way for enhanced therapeutic interventions and novel industrial applications in the future.
2
关键词
Keywords
references
MURPHY B , GRIMSHAW S , HOPTROFF M , et al . Alteration of barrier properties, stratum corneum ceramides and microbiome composition in response to lotion application on cosmetic dry skin [J ] . Scientific Reports , 2022 , 12 ( 1 ): 5223 .
FUJII M . The pathogenic and therapeutic implications of ceramide abnormalities in atopic dermatitis [J ] . Cells , 2021 , 10 ( 9 ): 2386 .
SCHMITT T , NEUBERT R H H . State of the art in stratum corneum research: the biophysical properties of ceramides [J ] . Chemistry and Physics of Lipids , 2018 , 216 : 91 - 103 .
CHA H J , HE C F , ZHAO H , et al . Intercellular and intracellular functions of ceramides and their metabolites in skin (Review) [J ] . International Journal of Molecular Medicine , 2016 , 38 ( 1 ): 16 - 22 .
FEINGOLD K R . Thematic review series: Skin Lipids. The role of epidermal lipids in cutaneous permeability barrier homeostasis [J ] . Journal of Lipid Research , 2007 , 48 ( 12 ): 2531 - 2546 .
VAN SMEDEN J , HOPPEL L , VAN DER HEIJDEN R , et al . LC/MS analysis of stratum corneum lipids: ceramide profiling and discovery[S] [J ] . Journal of Lipid Research , 2011 , 52 ( 6 ): 1211 - 1221 .
MASUKAWA Y , NARITA H , SHIMIZU E , et al . Characterization of overall ceramide species in human stratum corneum s [J ] . Journal of Lipid Research , 2008 , 49 ( 7 ): 1466 - 1476 .
T’KINDT R , JORGE L , DUMONT E , et al . Profiling and characterizing skin ceramides using reversed-phase liquid chromatography-quadrupole time-of-flight mass spectrometry [J ] . Analytical Chemistry , 2012 , 84 ( 1 ): 403 - 411 .
LI X , YANG Q , ZHENG J , et al . Efficacy and safety of a topical moisturizer containing linoleic acid and ceramide for mild-to-moderate psoriasis vulgaris: a multicenter randomized controlled trial [J ] . Dermatologic Therapy , 2020 , 33 ( 6 ): e14263 .
SHIN K O , MIHARA H , ISHIDA K , et al . Exogenous ceramide serves as a precursor to endogenous ceramide synthesis and as a modulator of keratinocyte differentiation [J ] . Cells , 2022 , 11 ( 11 ): 1742 .
UCHIDA Y , PARK K . Ceramides in skin health and disease: an update [J ] . American Journal of Clinical Dermatology , 2021 , 22 ( 6 ): 853 - 866 .
SPADA F , HARRISON I P , BARNES T M , et al . A daily regimen of a ceramide-dominant moisturizing cream and cleanser restores the skin permeability barrier in adults with moderate eczema: a randomized trial [J ] . Dermatologic Therapy , 2021 , 34 ( 4 ): e14970 .
CAO Y , ZHANG X H , HE X F , et al . Efficacy of ceramide-containing sunscreen on skin barrier [J ] . Journal of Cosmetic Dermatology , 2024 , 23 ( 2 ): 525 - 528 .
ZHENG Y , HUNT R L , VILLARUZ A E , et al . Commensal Staphylococcus epidermidis contributes to skin barrier homeostasis by generating protective ceramides [J ] . Cell Host & Microbe , 2022 , 30 ( 3 ): 301 - 313.e9 .
KIM D S , KIM S Y , CHUNG J H , et al . Delayed ERK activation by ceramide reduces melanin synthesis in human melanocytes [J ] . Cellular Signalling , 2002 , 14 ( 9 ): 779 - 785 .
PHILIPS N , TUASON M , CHANG T , et al . Differential effects of ceramide on cell viability and extracellular matrix remodeling in keratinocytes and fibroblasts [J ] . Skin Pharmacology and Physiology , 2009 , 22 ( 3 ): 151 - 157 .
FISCHER C L , DRAKE D R , DAWSON D V , et al . Antibacterial activity of sphingoid bases and fatty acids against Gram-positive and Gram-negative bacteria [J ] . Antimicrobial Agents and Chemotherapy , 2012 , 56 ( 3 ): 1157 - 1161 .
BIBEL D J , ALY R , SHINEFIELD H R . Antimicrobial activity of sphingosines [J ] . Journal of Investigative Dermatology , 1992 , 98 ( 3 ): 269 - 273 .
DONGFACK M D J , LALLEMAND M C , KUETE V , et al . A new sphingolipid and furanocoumarins with antimicrobial activity from Ficus exasperata [J ] . Chemical & Pharmaceutical Bulletin , 2012 , 60 ( 8 ): 1072 - 1075 .
BECAM J , WALTER T , BURGERT A , et al . Antibacterial activity of ceramide and cerami de analogs against pathogenic Neisseria [J ] . Scientific Reports , 2017 , 7 ( 1 ): 17627 .
戚建华 , 边凌林 , 罗燕 , 等 . 一种神经酰胺类化合物和应用 : CN106631871A [P ] . 2017-05-10 .
QI J H , BIAN L L , LUO Y , et al . A ceramide compound and application thereof : CN106631871A [P ] . 2017-05-10 .
OHTA K , HIRAKI S , MIYANABE M , et al . Appearance of intact molecules of dietary ceramides prepared from soy sauce lees and rice glucosylceramides in mouse plasma [J ] . Journal of Agricultural and Food Chemistry , 2021 , 69 ( 32 ): 9188 - 9198 .
MORAD S A F , CABOT M C . Ceramide-orchestrated signalling in cancer cells [J ] . Nature Reviews Cancer , 2013 , 13 ( 1 ): 51 - 65 .
CASTRO B M , PRIETO M , SILVA L C . Ceramide: a simple sphingolipid with unique biophysical properties [J ] . Progress in Lipid Research , 2014 , 54 : 53 - 67 .
ZHANG Y H , VASKO M R , NICOL G D . Ceramide, a putative second messenger for nerve growth factor, modulates the TTX-resistant Na + current and delayed rectifier K + current in rat sensory neurons [J ] . The Journal of Physiology , 2002 , 544 ( 2 ): 385 - 402 .
ASHLEY COWART L , OBEID L M . Yeast sphingolipids: recent developments in understanding biosynthesis, regulation, and function [J ] . Biochimica et Biophysica Acta , 2007 , 1771 ( 3 ): 421 - 431 .
NICHOLSON R J , NORRIS M K , POSS A M , et al . The lard works in mysterious ways: ceramides in nutrition-linked chronic disease [J ] . Annual Review of Nutrition , 2022 , 42 : 115 - 144 .
OHTA K , HIRAKI S , MIYANABE M , et al . Dietary ceramide prepared from soy sauce lees improves skin barrier function in hairless mice [J ] . Journal of Oleo Science , 2021 , 70 ( 9 ): 1325 - 1334 .
ZHU F F , ZHAO B , HU B , et al . Review of available “extraction + purification” methods of natural ceramides and their feasibility for sewage sludge analysis [J ] . Environmental Science and Pollution Research , 2023 , 30 ( 26 ): 68022 - 68053 .
张可青 , 王建华 , 于姝燕 , 等 . 植物中神经酰胺类化合物提取工艺研究进展 [J ] . 内蒙古中医药 , 2022 , 41 ( 6 ): 131 - 133 .
ZHANG K Q , WANG J H , YU S Y , et al . Research progress on extraction technology of ceramides from plants [J ] . Inner Mongolia Journal of Traditional Chinese Medicine , 2022 , 41 ( 6 ): 131 - 133 .
YAHYA N A , ATTAN N , WAHAB R A . An overview of cosmeceutically relevant plant extracts and strategies for extraction of plant-based bioactive compounds [J ] . Food and Bioproducts Processing , 2018 , 112 : 69 - 85 .
OJHA K S , AZNAR R , O’DONNELL C , et al . Ultrasound technology for the extraction of biologically active molecules from plant, animal and marine sources [J ] . TrAC Trends in Analytical Chemistry , 2020 , 122 : 115663 .
WILD R , SCHMIDT R R . Sphingosine and phytosphingosine from D- threose synthesis of a 4-keto-ceramide [J ] . Tetrahedron: Asymmetry , 1994 , 5 ( 11 ): 2195 - 2208 .
TORSSELL S , SOMFAI P . A practical synthesis of D- erythro -sphingosine using a cross-metathesis approach [J ] . Organic & Biomolecular Chemistry , 2004 , 2 ( 11 ): 1643 - 1646 .
CHAUDHARI V D , AJISH KUMAR K S , DHAVALE D D . An efficient synthesis of D- erythro - and D- threo -sphingosine from D-glucose: olefin cross-metathesis approach [J ] . Organic Letters , 2005 , 7 ( 26 ): 5805 - 5807 .
YAMAMOTO T , HASEGAWA H , HAKOGI T , et al . Versatile synthetic method for sphingolipids and functionalized sphingosine derivatives via olefin cross metathesis [J ] . Organic Letters , 2006 , 8 ( 24 ): 5569 - 5572 .
YANG H , LIEBESKIND L S . A concise and scalable synthesis of high enantiopurity (–)-D- erythro -sphingosine using peptidyl thiol ester-boronic acid cross-coupling [J ] . Organic Letters , 2007 , 9 ( 16 ): 2993 - 2995 .
禹柄英 , 张元僖 , 朱泳协 , 等 . 新型的类神经酰胺化合物其及其制备方法 : CN104854081A [P ] . 2015-08-19 .
WOO B Y , JANG W H , JOO Y H , et al . The invention discloses a novel ceramide-like compound and a preparation method thereof : CN104854081A [P ] . 2015-08-19 .
刘希望 . 神经酰胺类似化合物的合成及其生物活性研究 [D ] . 咸阳 : 西北农林科技大学 , 2010 .
LIU X W . Synthesis and bioactivity of ceramide-like compounds [D ] . Xianyang : Northwest Agriculture & Forestry University , 2010 .
CRITCHLEY P , RAWLINGS A V , SCOTT I R . Synthetic pseudoceramide and cosmetic compositions thereof : US5206020A [P ] . 1993-04-27 .
MOTION K R , JANOUSEK A , WATKINS S D . Hydroxy alkyl amides of dicarboxylic acids and their use in cosmetic compositions : US5656668A [P ] . 1997-08-12 .
BAIK I S , LEE J G , PARK B D , et al . Pseudoceramides, and dermatologic external preparations containing the same : US6221371B1 [P ] . 2001-04-24 .
PARK B D , LEE K M , PARK I J , et al . Novel pseudoceramides and their synthesis using alkyl ketene dimer [J ] . Journal of the Society of Cosmetic Scientists of Korea , 1997 , 23 : 92 - 96 .
杨超文 , 叶柳 . 含共轭羧酸的神经酰胺类化合物及其制备方法和应用 : CN115433100A [P ] . 2022-12-06 .
YANG C W , YE L . Ceramide compounds containing conjugated carboxylic acids, preparation method and application thereof : CN115433100A [P ] . 2022-12-06 .
吴江 , 张伟 , 朱纯银 . 一种酰胺的合成方法及其在神经酰胺 3 制备上的应用 : CN 110078635 A [P ] . 2019-08-02 .
WU J , ZHANG W , ZHU C Y . An amide synthesis method and its application in the preparation of ceramide 3 : CN 110078635 A [P ] . 2019-08-02 .
M . F . 埃克施泰因 , M.D .范洛格切姆, H.H .文克, 等. 制备鞘脂的方法: CN110317840A [P ] . 2019-10-11 .
ECKSTEIN M F , VAN LOGCHEM M D , WENK H H , et al . Method for preparing sphingolipid : CN110317840A [P ] . 2019-10-11 .
F . 霍尔曼 , O .图姆, P .格热比克, 等. 使用脂肪酶和脂肪酸甘油酯通过溶性鞘脂的酶促N-酰化反应制备鞘脂的方法: CN102057050B [P ] . 2014-06-11 .
HOLMANN F , TUM O , GRZEBYK P , et al . Method of preparing sphingolipid by enzymatic N -acylation of soluble sphingolipid using lipase and fatty acid glyceride : CN102057050B [P ] . 2014-06-11 .
ZHANG X Y , MA Y J , OUYANG B , et al . Efficient lipase-catalyzed synthesis of ceramide Ⅲ series compounds in an eco-friendly solvent [J ] . Molecular Catalysis , 2024 , 558 : 114006 .
HE L , BYUN H S , BITTMAN R . Stereoselective preparation of ceramide and its skeleton backbone modified analogues via cyclic thionocarbonate intermediates derived by catalytic asymmetric dihydroxylation of α,β-unsaturated ester precursors [J ] . The Journal of Organic Chemistry , 2000 , 65 ( 22 ): 7627 - 7633 .
RAI A N , BASU A . Synthesis of the glycosphingolipid β-galactosyl ceramide and analogues via olefin cross metathesis [J ] . The Journal of Organic Chemistry , 2005 , 70 ( 20 ): 8228 - 8230 .
NAKAMURA T , SHIOZAKI M . Stereoselective synthesis of D- erythro -sphingosine and L- lyxo -phytosphingosine [J ] . Tetrahedron , 2001 , 57 ( 44 ): 9087 - 9092 .
LU X Q , BITTMAN R . Efficient and versatile synthesis of (2 S ,3 R )-sphingosine and its 2-azido-3- O -benzylsphingosine analogue [J ] . Tetrahedron Letters , 2005 , 46 ( 11 ): 1873 - 1875 .
DUCLOS R I . The total syntheses of D- erythro -sphingosine, N -palmitoylsphingosine (ceramide), and glucosylceramide (cerebroside) via an azidosphingosine analog [J ] . Chemistry and Physics of Lipids , 2001 , 111 ( 2 ): 111 - 138 .
朴尽五 , 李知愿 , 全圣贤 , 等 . 新型类神经酰胺化合物及其用途 : CN111201216A [P ] . 2020-05-26 .
PARK J O , LEE J W , JEON S H , et al . Novel ceramide-like compounds and their applications : CN111201216A [P ] . 2020-05-26 .
F . 霍尔曼 , O .图姆, C .特勒, 等. 使用真菌脂肪酶和脂肪酸烷基酯通过溶性鞘脂的酶促N-酰化反应制备鞘脂的方法: CN102057049B [P ] . 2014-10-01 .
HOLMANN F , TUM O , TELLERET C , et al . Sphingolipid is prepared by enzymatic N -acylation of soluble sphingolipid using fungal lipase and fatty acid alkyl ester : CN102057049B [P ] . 2014-10-01 .
WICKERHAM L J , STODOLA F H . Formation of extracellular sphingolipides by microorganisms.Ⅰ. Tetraacetylphyto-sphingosine from Hansenula ciferri [J ] . Journal of Bacteriology , 1960 , 80 ( 4 ): 484 - 491 .
SCHORSCH C , KÖHLER T , ANDREA H , et al . High-level production of tetraacetyl phytosphingosine (TAPS) by combined genetic engineering of sphingoid base biosynthesis and L-serine availability in the non-conventional yeast Pichia ciferrii [J ] . Metabolic Engineering , 2012 , 14 ( 2 ): 172 - 184 .
TER VELD F , WOLFF D , SCHORSCH C , et al . Production of tetraacetyl phytosphingosine (TAPS) in Wickerhamomyces ciferrii is catalyzed by acetyltransferases Sli1p and Atf2p [J ] . Applied Microbiology and Biotechnology , 2013 , 97 ( 19 ): 8537 - 8546 .
PARK S B , TRAN Q G , RYU A J , et al . Fluorescence-activated cell sorting-mediated directed evolution of Wickerhamomyces ciferrii for enhanced production of t etraacetyl phytosphingosine [J ] . Korean Journal of Chemical Engineering , 2022 , 39 ( 4 ): 1004 - 1010 .
HAN C , JANG M , KIM M J , et al . Engineering Yarrowia lipolytica for de novo production of tetraacetyl phytosphingosine [J ] . Journal of Applied Microbiology , 2021 , 130 ( 6 ): 1981 - 1992 .
CHOI J Y , HWANG H J , CHO W Y , et al . Differences in the fatty acid profile, morphology, and tetraacetylphytosphingosine-forming capability between wild-type and mutant Wickerhamomyces ciferrii [J ] . Frontiers in Bioengineering and Biotechnology , 2021 , 9 : 662979 .
纪晓俊 , 崔柳伟 , 王凯峰 , 等 . 一株高产四乙酰基植物鞘氨醇的菌株及其应用 : CN117070382A [P ] . 2023-11-17 .
JI X J , CUI L W , WANG K F , et al . A strain with high yield of tetraacetyl phytosphingosine and its application : CN117070382A [P ] . 2023-11-17 .
PARK C S , JEONG J H , HONG S Y , et al . Yeast Pichia ciferrii : US6194196B1 [P ] . 2001-02-27 .
张天萌 , 刘金钊 , 朱倩倩 , 等 . 一种高产鞘脂类微生物菌株、它的筛选方法和它的用途 : CN114736815A [P ] . 2022-07-12 .
ZHANG T M , LIU J Z , ZHU Q Q , et al . A high-yielding sphingolipid microbial strain, its screening method and its use : CN114736815A [P ] . 2022-07-12 .
孙杰 , 谢朋天 , 魏春 , 等 . 一种高产植物鞘氨醇的酿酒酵母菌株 : CN116103176A [P ] . 2023-05-12 .
SUN J , XIE P T , WEI C , et al . A strain of Saccharomyces cerevisiae with high yield of sphingosine : CN116103176A [P ] . 2023-05-12 .
M . 施瓦布 , M . 巴鲍, D . 费希尔, 等. 生产植物鞘氨醇或二氢神经鞘氨醇的方法: CN108473968A [P ] . 2018-08-31 .
SCHWAB M , BABAU M , FISCHER D , et al . Method for producing phytosphingosine or dihydrosphingosine : CN108473968A [P ] . 2018-08-31 .
KWUN K H , LEE J H , RHO K H , et al . Production of ceramide with Saccharomyces cerevisiae [J ] . Applied Biochemistry and Biotechnology , 2006 , 133 ( 3 ): 203 - 210 .
KIM S K , NOH Y H , KOO J R , et al . Effect of expression of genes in the sphingolipid synthesis pathway on the biosynthesis of ceramide in Saccharomyces cerevisiae [J ] . Journal of Microbiology and Biotechnology , 2010 , 20 ( 2 ): 356 - 362 .
KIM S K , NOH Y H , KOO J R , et al . Effects of expression of lcb1 / lcb2 and lac1 / lag1 genes on the biosynthesis of ceramides [J ] . Biotechnology and Bioprocess Engineering , 2011 , 16 ( 1 ): 1 - 6 .
MURAKAMI S , SHIMAMOTO T , NAGANO H , et al . Producing human ceramide-NS by metabolic engineering using yeast Saccharomyces cerevisiae [J ] . Scientific Reports , 2015 , 5 : 16319 .
黄铭 , 吴佳欣 , 张目 , 等 . 毕赤酵母PAS_chr4_0427基因敲除促进神经酰胺合成 [J ] . 食品与发酵工业 , 2024 , 50 ( 17 ): 17 - 22 .
HUANG M , WU J X , ZHANG M , et al . Knockout of PAS_chr4_0427 promotes ceramide synthesis in Pichia pastoris [J ] . Food and Fermentation Industries , 2024 , 50 ( 17 ): 17 - 22 .
KURTZMAN C P . Phylogeny of the ascomycetous yeasts and the renaming of Pichia anomala to Wickerhamomyces anomalus [J ] . Antonie Van Leeuwenhoek , 2011 , 99 ( 1 ): 13 - 23 .
MAISTER H G , ROGOVIN S P , STODOLA F H , et al . Formation of extracellular sphingolipids by microorganisms: Ⅳ. Pilot-plant production of tetraacetylphytosphingosine by Hansenula ciferrii [J ] . Applied Microbiology , 1962 , 10 ( 5 ): 401 - 406 .
S . 舍费尔 , M.A .范登贝尔赫, D .博尔格尔, 等. 使用遗传工程化的微生物菌株的改进的鞘氨醇类碱的生产: CN101490260A [P ] . 2009-07-22 .
SCHAFFER S , VAN DEN BERGH M A , BOERGEL D , et al . Improved production of sphingoid bases using genetically engineered microbial strains : CN101490260A [P ] . 2009-07-22 .
OLEA-OZUNA R J , POGGIO S , EDBERGSTRÖM , et al . Five structural genes required for ceramide synthesis in Caulobacter and for bacterial survival [J ] . Environmental Microbiology , 2021 , 23 ( 1 ): 143 - 159 .
FURUYA H , IDE Y , HAMAMOTO M , et al . Isolation of a novel bacterium, Blautia glucerasei sp. nov., hydrolyzing plant glucosylceramide to ceramide [J ] . Archives of Microbiology , 2010 , 192 ( 5 ): 365 - 372 .
HALAMKA T A , GARCIA A , EVANS T W , et al . Occurrence of ceramides in the Acidobacterium solibacter usitatus : implications for bacterial physiology and sphingolipids in soils [J ] . Frontiers in Geochemistry , 2024 , 2 : 1400278 .
STANKEVICIUTE G , TANG P J , ASHLEY B , et al . Convergent evolution of bacterial ceramide synthesis [J ] . Nature Chemical Biology , 2022 , 18 ( 3 ): 305 - 312 .
BROWN E M , KE X B , HITCHCOCK D , et al . Bacteroides -derived sphingolipids are critical for maintaining intestinal homeostasis and symbiosis [J ] . Cell Host & Microbe , 2019 , 25 ( 5 ): 668 - 680.e7 .
YAMAJI T , HANADA K . Sphingolipid metabolism and interorganellar transport: localization of sphingolipid enzymes and lipid transfer proteins [J ] . Traffic , 2015 , 16 ( 2 ): 101 - 122 .
CINGOLANI F , FUTERMAN A H , CASAS J . Ceramide synthases in biomedical research [J ] . Chemistry and Physics of Lipids , 2016 , 197 : 25 - 32 .
SAWAI H , OKAMOTO Y , LUBERTO C , et al . Identification of ISC1 (YER019w) as inositol phosphosphingolipid phospholipase C in Saccharomyces cerevisiae [J ] . The Journal of Biological Chemistry , 2000 , 275 ( 50 ): 39793 - 39798 .
DICKSON R C . Roles for sphingolipids in Saccharomyces cerevisiae [J ] . Advances in Experimental Medicine and Biology , 2010 , 688 : 217 - 231 .
ANDO H , KOMURA N . Recent progress in the synthesis of glycosphingolipids [J ] . Current Opinion in Chemical Biology , 2024 , 78 : 102423 .
WENNEKES T , VAN DEN BERG R J B H N , BOOT R G , et al . Glycosphingolipids-nature, function, and pharmacological modulation [J ] . Angewandte Chemie International Edition , 2009 , 48 ( 47 ): 8848 - 8869 .
HARRISON P J , DUNN T M , CAMPOPIANO D J . Sphingolipid biosynthesis in man and microbes [J ] . Natural Product Reports , 2018 , 35 ( 9 ): 921 - 954 .
YARD B A , CARTER L G , JOHNSON K A , et al . The structure of serine palmitoyltransferase; gateway to sphingolipid biosynthesis [J ] . Journal of Molecular Biology , 2007 , 370 ( 5 ): 870 - 886 .
HANADA K . Serine palmitoyltransferase, a key enzyme of sphingolipid metabolism [J ] . Biochimica et Biophysica Acta , 2003 , 1632 ( 1-3 ): 16 - 30 .
GABLE K , HAN G S , MONAGHAN E , et al . Mutations in the yeast LCB1 and LCB2 genes, including those corresponding to the hereditary sensory neuropathy typeⅠmutations, dominantly inactivate serine palmitoyltransferase* [J ] . Journal of Biological Chemistry , 2002 , 277 ( 12 ): 10194 - 10200 .
GABLE K , SLIFE H , BACIKOVA D , et al . Tsc3p is an 80-amino acid protein associated with serine palmitoyltransferase and required for optimal enzyme activity [J ] . Journal of Biological Chemistry , 2000 , 275 ( 11 ): 7597 - 7603 .
REN J H , SAIED E M , ZHONG A , et al . Tsc3 regulates SPT amino acid choice in Saccharomyces cerevisiae by promoting alanine in the sphingolipid pathway [J ] . Journal of Lipid Research , 2018 , 59 ( 11 ): 2126 - 2139 .
SCHÄFER J H , KÖRNER C , ESCH B M , et al . Structure of the ceramide-bound SPOTS complex [J ] . Nature Communications , 2023 , 14 ( 1 ): 6196 .
BEELER T , BACIKOVA D , GABLE K , et al . The Saccharomyces cerevisiae TSC10 /YBR265w gene encoding 3-ketosphinganine reductase is identified in a screen for temperature-sensitive suppressors of the Ca 2+ -sensitive csg2Δ mutant [J ] . Journal of Biological Chemistry , 1998 , 273 ( 46 ): 30688 - 30694 .
BRESLOW D K , COLLINS S R , BODENMILLER B , et al . Orm family proteins mediate sphingolipid homeostasis [J ] . Nature , 2010 , 463 ( 7284 ): 1048 - 1053 .
LIU Q , CHAN A K N , CHANG W H , et al . 3-Ketodihydrosphingosine reductase maintains ER homeostasis and unfolded protein response in leukemia [J ] . Leukemia , 2022 , 36 ( 1 ): 100 - 110 .
ZHAO P Q , ZHUANG Z W , GUAN X Y , et al . Crystal structure of the 3-ketodihydrosphingosine reductase TSC10 from Cryptococcus neoformans [J ] . Biochemical and Biophysical Research Communications , 2023 , 670 : 73 - 78 .
SCHORLING S , VALLÉE B , BARZ W P , et al . Lag1p and Lac1p are essential for the acyl-CoA-dependent ceramide synthase reaction in Saccharomyces cerevisae [J ] . Molecular Biology of the Cell , 2001 , 12 ( 11 ): 3417 - 3427 .
GUILLAS I , KIRCHMAN P A , CHUARD R , et al . C 26 -CoA-dependent ceramide synthesis of Saccharomyces cerevisiae is operated by Lag1p and Lac1p [J ] . The EMBO Journal , 2001 , 20 ( 11 ): 2655 - 2665 .
SCHÄFER J H , CLAUSMEYER L , KÖRNER C , et al . Structure of the yeast ceramide synthase [J/OL ] . Nature Structural & Molecular Biology . ( 2024-11-11 )[ 2024-11-11 ] . https://doi.org/10.1038/s41594-024-01415-2 https://doi.org/10.1038/s41594-024-01415-2 .
ZHANG M M , LI Z Y , LIU Y W , et al . The ceramide synthase (CERS/LASS) family: functions involved in cancer progression [J ] . Cellular Oncology , 2023 , 46 ( 4 ): 825 - 845 .
XIE T , FANG Q , ZHANG Z K , et al . Structure and mechanism of a eukaryotic ceramide synthase complex [J ] . The EMBO Journal , 2023 , 42 ( 24 ): e114889 .
COWART L A , HANNUN Y A . Selective substrate supply in the regulation of yeast de novo sphingolipid synthesis [J ] . The Journal of Biological Chemistry , 2007 , 282 ( 16 ): 12330 - 12340 .
HANADA K , HARA T , NISHIJIMA M . Purification of the serine palmitoyltransferase complex responsible for sphingoid base synthesis by using affinity peptide chromatography techniques [J ] . The Journal of Biological Chemistry , 2000 , 275 ( 12 ): 8409 - 8415 .
SCHWAB M , BABAU M , FISCHER D , et al . Method for producing phytosphingosine or sphinganine : US20180179562 [P ] . 2021-09-07 .
HAN S M , LONE M A , SCHNEITER R , et al . Orm1 and Orm2 are conserved endoplasmic reticulum membrane proteins regulating lipid homeostasis and protein quality control [J ] . Proceedings of the National Academy of Sciences of the United States of America , 2010 , 107 ( 13 ): 5851 - 5856 .
LIU M , HUANG C J , POLU S R , et al . Regulation of sphingolipid synthesis through Orm1 and Orm2 in yeast [J ] . Journal of Cell Science , 2012 , 125 ( Pt 10 ): 2428 - 2435 .
RODRIGUEZ-GALLARDO S , KUROKAWA K , SABIDO-BOZO S , et al . Ceramide chain length-dependent protein sorting into selective endoplasmic reticulum exit sites [J ] . Science Advances , 2020 , 6 ( 50 ): eaba8237 .
LIU L K , CHOUDHARY V , TOULMAY A , et al . An inducible ER-Golgi tether facilitates ceramide transport to alleviate lipotoxicity [J ] . The Journal of Cell Biology , 2017 , 216 ( 1 ): 131 - 147 .
IKEDA A , SCHLARMANN P , KUROKAWA K , et al . Tricalbins are required for non-vesicular ceramide transport at ER-Golgi contacts and modulate lipid droplet biogenesis [J ] . iScience , 2020 , 23 ( 10 ): 101603 .
ZELNIK I D , VENTURA A E , KIM J L , et al . The role of ceramide in regulating endoplasmic reticulum function [J ] . Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids , 2020 , 1865 ( 1 ): 158489 .
LIU P T , SUN L , SUN Y X , et al . Decreased fluidity of cell membranes causes a metal ion deficiency in recombinant Saccharomyces cerevisiae producing carotenoids [J ] . Journal of Industrial Microbiology & Biotechnology , 2016 , 43 ( 4 ): 525 - 535 .
BU X , LIN J Y , CHENG J , et al . Engineering endogenous ABC transporter with improving ATP supply and membrane flexibility enhances the secretion of β-carotene in Saccharomyces cerevisiae [J ] . Biotechnology for Biofuels , 2020 , 13 : 168 .
0
Views
1
下载量
1
CSCD
- L-PDFDownload
- WORDDownload
- Meta-XMLDownload
- BibTeXDownload
- EndnoteDownload
- RefMan Download
- NoteExpressDownload
- NoteFirstDownload
Publicity Resources
Related Articles
Related Author
Related Institution
- Postal code:100000
- Tel:010-64519339
- Technical support is provided by Beijing Founder electronics co., LTD 京ICP备09064830号-19
京公网安备11010802024621 - It is recommended to read the content of this site in Chrome&IE9+. Please switch to extreme mode in browser 360.
- Cookies We use cookies to help provide and enhance our service and tailor content. By continuing, you agree to the use of cookies.