Cellulose synthase (UDP-forming): Difference between revisions

cellulose synthase (UDP-forming)
cellulose synthase (UDP-forming)
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EC no.	2.4.1.12
CAS no.	9027-19-4
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cellulose synthase (UDP-forming)
cellulose synthase (UDP-forming)
Identifiers
EC no.	2.4.1.12
CAS no.	9027-19-4
Databases
IntEnz	IntEnz view
BRENDA	BRENDA entry
ExPASy	NiceZyme view
KEGG	KEGG entry
MetaCyc	metabolic pathway
PRIAM	profile
PDB structures	RCSB PDB PDBe PDBsum
Gene Ontology	AmiGO / QuickGO
PMC
Search
PMC	articles
PubMed	articles
NCBI	proteins

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In enzymology, a cellulose synthase (UDP-forming) (EC 2.4.1.12) is an enzyme that catalyzes the chemical reaction

UDP-glucose + (1,4-beta-D-glucosyl)_n

\rightleftharpoons

UDP + (1,4-beta-D-glucosyl)_n+1

Thus, the two substrates of this enzyme are UDP-glucose and a chain of 1,4-beta-D-glucosyl residues, whereas its two products are UDP and an elongated chain of glucosyl residues. Glucosyl is the glycosyl of glucose, a chain of 1,4-beta-D-glucosyl residues is cellulose, and enzymes of this class therefore play an important role in the synthesis of cellulose.

This enzyme belongs to the family of hexosyltransferases, specifically to the glycosyltransferases. The systematic name of this enzyme class is UDP-glucose:1,4-beta-D-glucan 4-beta-D-glucosyltransferase. Other names in common use include UDP-glucose-beta-glucan glucosyltransferase, UDP-glucose-cellulose glucosyltransferase, GS-I, beta-1,4-glucosyltransferase, uridine diphosphoglucose-1,4-beta-glucan glucosyltransferase, beta-1,4-glucan synthase, beta-1,4-glucan synthetase, beta-glucan synthase, 1,4-beta-D-glucan synthase, 1,4-beta-glucan synthase, glucan synthase, UDP-glucose-1,4-beta-glucan glucosyltransferase, and uridine diphosphoglucose-cellulose glucosyltransferase.

References

GLASER L (1958). "The synthesis of cellulose in cell-free extracts of Acetobacter xylinum". J. Biol. Chem. 232 (2): 627–36. PMID 13549448.

This enzyme-related article is a stub. You can help Wikipedia by expanding it.

Cellulose Synthase CelluloseItalic text Cellulose is an aggregation of unbranched polymer chains made of β-1,4-linked glucose residues that makes up a large portion of primary and secondary cell walls.^[1] ^[2] ^[3] ^[4]. Although important for plants, it is also synthesized by most algae, some bacteria, and some animals ^[5] ^[6] ^[7]^[8]. Worldwide, 2 × 1011 tons of cellulose microfibrils are produced ^[9], which serves as a critical source of renewable biofuels and other biological-based products, such as lumber, fuel, fodder, paper and cotton ^[2]^[10]. Purpose of cellulose These microfibrils are made on the surface of cell membranes to reinforce cells walls, which has been researched extensively by plant biochemists and cell biologist because 1) they regulate cellular morphogenesis and 2) they serve alongside many other constituents (i.e. lignin, hemicellulose, pectin) in the cell wall as a strong structural support and cell shape. ^[10]. Without these support structures, cell growth would cause a cell to swell and spread in all directions, thus losing its shape viability ^[11] Cellulose synthase structure

        Plant cellulose synthases belong to the family of glycosyltransferases, which are proteins involved in the biosynthesis and hydrolysis of the bulk of earth’s biomass ^[12].  Cellulose is synthesized by a large cellulose synthase complexes (CSCs), which are comprised of synthase protein isoform (CesA) that are arranged into a unique hexagonal structure known as a “particle rosette” 50 nm wide and 30-35 nm tall ^[13]^[14] (Giddings et al. 1980, Bowling and Brown 2008, Yin et al. 2009).  There are more than 20 of these full-length integral membrane proteins, each of which is around 1000 amino acids long (Olek et al. 2014, Richmond 2000). These rosettes, formerly known as granules, were first discovered in 1972 by electron microscopy in green algae species Cladophora and Chaetomorpha (Robinson et al. 1972).  Solution x-ray scattering have shown that CesAs are at the surface of a plant cell and are elongated monomers with a two catalytic domains that fuse together into dimers.  The center of the dimers is the main point of catalytic activity. Since cellulose is made in all cell walls, CesA proteins are present in all tissues and cell types of plants.  Nonetheless, there are different types of CesA, some tissue types may have varying concentrations of one over another.  For example, the AtCesA1 (RSW1) protein is involved in the biosynthesis of primary cell walls throughout the whole plant while the AtCesA7 (IRX3) protein is only expressed in the stem for secondary cell wall production (Richmond 2000).

Cellulose synthase activity

          Cellulose biosynthesis is the process during which separate homogeneous β-1,4-glucan chains, ranging from 2,000 to 25,000 glucose residues in length, are synthesized and then immediately hydrogen bond with one another to form rigid crystalline arrays, or microfibrils.  Microfibrils in the primary cell wall are approximately 36 chains long while those of the secondary cell wall are much larger, containing up to 1200 β-1,4-glucan chains (Cuter and Somerville 1997, Richmond 2000).  Uridine diphosphate-glucose (UDP), which is produced by the enzyme sucrose synthase (SuSy) that produces and transports UDP-glucose to the plasma membrane is the substrate used by cellulose synthase to produce the glucan chains.  (Heath 1974, Olek et al. 2014).  The rate at which glucose residues are synthesized per one glucan chain ranges from 300-1000 glucose residues per minute, the higher rate being more prevalent in secondary wall particles, such as in the xylem.   (Paredez et al. 2006, Wightman et al. 2009)

Supporting structures Microfibril synthesis is guided by cortical microtubules, which lie beneath the plasma membrane of elongating cells, in that they form a platform on which the CSCs can convert glucose molecules into the crystalline chains. The microtubule–microfibril alignment hypothesis proposes that cortical microtubules, which lie beneath the plasma membrane of elongating cells, provide tracks for CSCs that convert glucose molecules into crystalline cellulose microfibrils (Green 1962). The direct hypothesis postulates some types of direct linkage between CESA complexes and microtubules (Heath 1974). Additionally, the KORRIGAN (KOR1) protein is thought to be a critical component of cellulose synthesis in that it acts cellulose at the plasma membrane-cell wall interface. KOR1 interacts with a two specific CesA proteins, possibly by proof-reading and relieving stress created glucan chain synthesis by hydrolyzing disordered amorphous cellulose. (Mansoori et al. 2014) Environmental influences Cellulose synthesis activity is affected by many environmental stimuli, such as hormones, light, mechanical stimuli, nutrition, and interactions with the cytoskeleton. Interactions with these factors may influence cellulose deposition in that it affects the amount of substrate produced and the concentration and/or activity of CSCs in the plasma membrane.

Literature Cited -Bowling A.J., Brown R.M. Jr. 2008. The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants. Protoplasma 233: 115–127. -Campbell J.A., Davies G.J., Bulone V. Henrissat B. A. 1997. classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities. Biochemistry 326: 929–939. -Cutler, S. and C. Somerville. 1997. Cellulose synthesis: Cloning in silico. Current Biology 7: 108-111. -Giddings, T.H., D.L. Brower, and L.A. Staehelin. 1980. Visualization of particle complexes in the membrane of Micrastrias denticulata associated with the formation of cellulose fibrils in primary and secondary walls. Journal of Cellular Biology 84: 327–339 -Green, P. B. 1962. Mechanism for plant cellular morphogenesis. Science 138, 1404–1405. -Haigler, C. H., Ivanova-Datcheva, M., Hogan, P. S., Salnikov, V. V., Hwang, S., Martin, K., and Delmer, D. P. 2001. Carbon partitioning to cellulose synthesis. Plant Molecular Biology 47: 29–51. - Heath, I. B. 1974. A unified hypothesis for the role of membrane bound enzyme complexes and microtubules in plant cell wall synthesis. Journal of Theoretical Biology 48: 445–449. -Hogestsu, T. and H. Shibaoka. 1978. Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum. Planta 140: pp. 15–18 -Li, S., L. Lei, and Y. Gu. 2012. Functional analysis of complexes with mixed primary and secondary cellulose synthases. Plant Signaling & Behavior 8: e23179. -Lei, L., S. Li, and Y. Gu. 2012. Cellulose synthase complexes: composition and regulation. Frontiers of Plant Science 3: 75. -Lieth, H. 1975. Measurement of calorific values. Primary productivity of the biospher. Eds. H. Lieth and R. H. Whittaker. Springer, New York. 119-129. -Mansoori, N., J. Timmers, T. Desprez, C.L.A. Kamei, D.C.T Dees, J-P. Vinken, R.G.F. Visser, H. Hoefte, S. Vernhettes, L.M. Trindade. 2014. KORRIGAN1 interacts specifically with integral components of the cellulose synthase machinery. PLoS ONE 9: e112387. -Nakashima K1, Yamada L, Satou Y, Azuma J, Satoh N. 2004. The evolutionary origin of animal cellulose synthase. Development Genes and Evolution 214: 81-88. -Olek, A.T, C. Rayon, L. Makowski, H.R. Kim, P. Ciesielski, J. Badger, L.N. Paul, S. Ghosh, D. Kihara, M. Crowley, M.E. HImmel, J.T. Bolin, and N.C. Carpita. 2014. The structure of the catalytic domain of a plant cellulose synthase and its assembly into dimers. The Plant Cell 26: 2996-3009. - Paredez, A. R., Somerville, C. R., and Ehrhardt, D. W. 2006. Visualization of cellulose synthase demonstrates functional association with microtubules. Science 312: 1491–1495. -Richmond, T. 2000. Higher plant cellulose synthase. Genome Biology 1: 3001-3001.6. -Robinson, D. G., White, R. K., and Preston, R. D. (1972). Fine structure of swarmers of Cladophora and Chaetomorpha. III. Wall synthesis and development. Planta 107, 131–144. -Sethaphong, L., C.H. Haigler, J.D. Kubicki, J. Zimmer, D. Bonetta, S. DeBolt, I.G. Yingling. 2013. Tertiary model of a plant cellulose synthase. Proceedings of the National Academy of Sciences 110: 7512-7517. -Wightman, R., and Turner, S. R. 2008. The roles of the cytoskeleton during cellulose deposition at the secondary cell wall. Plant Journal 54: 794–805. -Yin, Y., J. Huang, and Y. Xu. 2009. The cellulose synthase superfamily in fully sequenced plants and algae. BMC Plant Biology 9: 99.

In enzymology, a cellulose synthase (UDP-forming) (EC 2.4.1.12) is an enzyme that catalyzes the chemical reaction

UDP-glucose + (1,4-beta-D-glucosyl)_n

\rightleftharpoons

UDP + (1,4-beta-D-glucosyl)_n+1

Thus, the two substrates of this enzyme are UDP-glucose and a chain of 1,4-beta-D-glucosyl residues, whereas its two products are UDP and an elongated chain of glucosyl residues. Glucosyl is the glycosyl of glucose, a chain of 1,4-beta-D-glucosyl residues is cellulose, and enzymes of this class therefore play an important role in the synthesis of cellulose.

This enzyme belongs to the family of hexosyltransferases, specifically to the glycosyltransferases. The systematic name of this enzyme class is UDP-glucose:1,4-beta-D-glucan 4-beta-D-glucosyltransferase. Other names in common use include UDP-glucose-beta-glucan glucosyltransferase, UDP-glucose-cellulose glucosyltransferase, GS-I, beta-1,4-glucosyltransferase, uridine diphosphoglucose-1,4-beta-glucan glucosyltransferase, beta-1,4-glucan synthase, beta-1,4-glucan synthetase, beta-glucan synthase, 1,4-beta-D-glucan synthase, 1,4-beta-glucan synthase, glucan synthase, UDP-glucose-1,4-beta-glucan glucosyltransferase, and uridine diphosphoglucose-cellulose glucosyltransferase.

References

^ Cutler, S (1997). "Classifaction of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities". Biochemistry. 326: 929–939. doi:10.1016/S0960-9822(06)00050-9. Retrieved 11 December 2014.
^ ^a ^b Olek, Rayon, Wakowski, Kim, Badger, Ghosh, Crowley, Himmel, Bolin, Carpita, AT, C, L. HR, P, J, LN, S, D, M, ME, NC (2014). "The structure of the catalytic domain of a plant cellulose synthase and its assembly into dimers". The Plant Cell. 26: 2996–3009. doi:http://dx.doi.org/10.1105/tpc.114.126862. {{cite journal}}: Check |doi= value (help); External link in |doi= (help)CS1 maint: multiple names: authors list (link)
^ Richmond, Todd (2000). "Higher plant cellulose synthase". Genome Biology. 1: 3001. doi:10.1186/gb-2000-1-4-reviews3001.{{cite journal}}: CS1 maint: unflagged free DOI (link)
^ Lei, Li, Gu, L, S, Y (2012). "Cellulose synthase complexes: composition and regulation". Frontiers of Plant Science. 3: 75. doi:10.3389/fpls.2012.00075.{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: unflagged free DOI (link)
^ Nakashima, Yamada, Satou, Azuma, Satoh, K, L, Y, J, N (2004). "The evolutionary origin of animal cellulose synthase". Development Genes and Evolution. 26: 2996–3009. PMID 14740209.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Yin, Huang, Xu, Y, J, Y (2009). "The cellulose synthase superfamily in fully sequenced plants and algae". BMC Plant Biology. 9: 99. doi:10.1186/1471-2229-9-99.{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: unflagged free DOI (link)
^ Sethaphong, Haigler, Kubicki, Zimmer, Bonetta, DeBolt, Yinling, L, CH, JD, J, D S, IG (2013). "Tertiary model of a plant cellulose synthase". Proceedings of the National Academy of Sciences. 110: 7512–7517. doi:10.1073/pnas.1301027110.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Li, Lei, Gu, S, L, Y (2012). "Functional analysis of complexes with mixed primary and secondary cellulose synthases". Plant Signaling and Behavior. 8: 23179.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Lieth, H (1975). Measurement of calorific values. Primary productivity of the biosphere. New York: Springer. pp. 119–129.
^ ^a ^b Cutler, Somerville, S, C (1997). "Cellulose synthesis: Cloning in silico". Current Biology. 7: 108–111. doi:10.1016/S0960-9822(06)00050-9.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Hogetsu, Shibaoka, T, H (1978). "Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum". Planta. 140: 445–449. doi:10.1007/BF00389374.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Campell, Davies, Bulone, Henrissat, JA, GJ, V, BA (1997). ". Classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities". Biochemistry. 326: 929–939. PMID PMC1219098. {{cite journal}}: Check |pmid= value (help)CS1 maint: multiple names: authors list (link)
^ Giddings, Brower, Staehelin, TH, DL, LA (1980). "formation of cellulose fibrils in primary and secondary walls". Journal of Cellular Biology. 84: 327–339.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Bowling, Brown, AJ, RM Jr (2008). "The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants". Protoplasma. 233: 115–127.{{cite journal}}: CS1 maint: multiple names: authors list (link)

GLASER L (1958). "The synthesis of cellulose in cell-free extracts of Acetobacter xylinum". J. Biol. Chem. 232 (2): 627–36. PMID 13549448.

This enzyme-related article is a stub. You can help Wikipedia by expanding it.

[1] Cutler, S (1997). "Classifaction of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities". Biochemistry. 326: 929–939. doi:10.1016/S0960-9822(06)00050-9. Retrieved 11 December 2014.

[Olek-2] Olek, Rayon, Wakowski, Kim, Badger, Ghosh, Crowley, Himmel, Bolin, Carpita, AT, C, L. HR, P, J, LN, S, D, M, ME, NC (2014). "The structure of the catalytic domain of a plant cellulose synthase and its assembly into dimers". The Plant Cell. 26: 2996–3009. doi:http://dx.doi.org/10.1105/tpc.114.126862. {{cite journal}}: Check |doi= value (help); External link in |doi= (help)CS1 maint: multiple names: authors list (link)

[3] Richmond, Todd (2000). "Higher plant cellulose synthase". Genome Biology. 1: 3001. doi:10.1186/gb-2000-1-4-reviews3001.{{cite journal}}: CS1 maint: unflagged free DOI (link)

[4] Lei, Li, Gu, L, S, Y (2012). "Cellulose synthase complexes: composition and regulation". Frontiers of Plant Science. 3: 75. doi:10.3389/fpls.2012.00075.{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: unflagged free DOI (link)

[Nakashima-5] Nakashima, Yamada, Satou, Azuma, Satoh, K, L, Y, J, N (2004). "The evolutionary origin of animal cellulose synthase". Development Genes and Evolution. 26: 2996–3009. PMID 14740209.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Yin-6] Yin, Huang, Xu, Y, J, Y (2009). "The cellulose synthase superfamily in fully sequenced plants and algae". BMC Plant Biology. 9: 99. doi:10.1186/1471-2229-9-99.{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: unflagged free DOI (link)

[Sethaphong-7] Sethaphong, Haigler, Kubicki, Zimmer, Bonetta, DeBolt, Yinling, L, CH, JD, J, D S, IG (2013). "Tertiary model of a plant cellulose synthase". Proceedings of the National Academy of Sciences. 110: 7512–7517. doi:10.1073/pnas.1301027110.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Li-8] Li, Lei, Gu, S, L, Y (2012). "Functional analysis of complexes with mixed primary and secondary cellulose synthases". Plant Signaling and Behavior. 8: 23179.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Lieth-9] Lieth, H (1975). Measurement of calorific values. Primary productivity of the biosphere. New York: Springer. pp. 119–129.

[Cutler-10] Cutler, Somerville, S, C (1997). "Cellulose synthesis: Cloning in silico". Current Biology. 7: 108–111. doi:10.1016/S0960-9822(06)00050-9.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Hogetsu-11] Hogetsu, Shibaoka, T, H (1978). "Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum". Planta. 140: 445–449. doi:10.1007/BF00389374.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Campbell-12] Campell, Davies, Bulone, Henrissat, JA, GJ, V, BA (1997). ". Classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities". Biochemistry. 326: 929–939. PMID PMC1219098. {{cite journal}}: Check |pmid= value (help)CS1 maint: multiple names: authors list (link)

[Giddings-13] Giddings, Brower, Staehelin, TH, DL, LA (1980). "formation of cellulose fibrils in primary and secondary walls". Journal of Cellular Biology. 84: 327–339.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[Bowling-14] Bowling, Brown, AJ, RM Jr (2008). "The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants". Protoplasma. 233: 115–127.{{cite journal}}: CS1 maint: multiple names: authors list (link)

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@@ Line 1: / Line 1: @@
+{{enzyme
+| name=cellulose synthase (UDP-forming)
+| EC_number = 2.4.1.12
+| CAS_number = 9027-19-4
+| IUBMB_EC_number = 2/4/1/12
+| GO_code = 0016760
+| image =
+| width =
+| caption =
+}}
+In [[enzymology]], a '''cellulose synthase (UDP-forming)''' ({{EC number|2.4.1.12}}) is an [[enzyme]] that [[catalysis|catalyzes]] the [[chemical reaction]]
+:UDP-glucose + (1,4-beta-D-glucosyl)<sub>n</sub> <math>\rightleftharpoons</math> UDP + (1,4-beta-D-glucosyl)<sub>n+1</sub>
+Thus, the two [[substrate (biochemistry)|substrates]] of this enzyme are [[UDP-glucose]] and a chain of 1,4-beta-D-glucosyl residues, whereas its two [[product (chemistry)|products]] are [[uridine diphosphate|UDP]] and an elongated chain of glucosyl residues. Glucosyl is the [[glycosyl]] of [[glucose]], a chain of 1,4-beta-D-glucosyl residues is [[cellulose]], and enzymes of this class therefore play an important role in the synthesis of cellulose.
+This enzyme belongs to the family of [[hexosyltransferase]]s, specifically to the [[glycosyltransferase]]s.  The systematic name of this enzyme class is UDP-glucose:1,4-beta-D-glucan 4-beta-D-glucosyltransferase. Other names in common use include '''UDP-glucose-beta-glucan glucosyltransferase''', '''UDP-glucose-cellulose glucosyltransferase''', '''GS-I''', '''beta-1,4-glucosyltransferase''', '''uridine diphosphoglucose-1,4-beta-glucan glucosyltransferase''', '''beta-1,4-glucan synthase''', '''beta-1,4-glucan synthetase''', '''beta-glucan synthase''', '''1,4-beta-D-glucan synthase''', '''1,4-beta-glucan synthase''', '''glucan synthase''', '''UDP-glucose-1,4-beta-glucan glucosyltransferase''', and '''uridine diphosphoglucose-cellulose glucosyltransferase'''.
+==References==
+{{reflist|1}}
+* {{cite journal | author = GLASER L | date = 1958 | title = The synthesis of cellulose in cell-free extracts of Acetobacter xylinum | journal = J. Biol. Chem.  | volume = 232 | pages = 627&ndash;36  | pmid = 13549448 | issue = 2 }}
+{{enzyme-stub}}
+[[Category:EC 2.4.1]]
+[[Category:Enzymes of unknown structure]]
+				   Cellulose Synthase
+'''Cellulose'''''Italic text''
+[[Cellulose]] is an aggregation of unbranched [[polymer]] chains made of β-1,4-linked [[glucose]] [[residues]] that makes up a large portion of primary and secondary [[cell walls]].<ref>{{cite journal|last1=Cutler|first1=S|title=Classifaction of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities|journal=Biochemistry|date=1997|volume=326|pages=929-939|doi=10.1016/S0960-9822(06)00050-9|url=http://www.sciencedirect.com/science/article/pii/S0960982206000509|accessdate=11 December 2014}}</ref> <ref name=Olek>{{cite journal|last1=Olek, Rayon, Wakowski, Kim, Badger, Ghosh, Crowley, Himmel, Bolin, Carpita|first1=AT, C, L. HR, P, J, LN, S, D, M, ME, NC|title=The structure of the catalytic domain of a plant cellulose synthase and its assembly into dimers|journal=The Plant Cell|date=2014|volume=26|pages=2996-3009|doi=http://dx.doi.org/10.1105/tpc.114.126862|url=http://www.plantcell.org/content/26/7/2996.full}}</ref> <ref>{{cite journal|last1=Richmond|first1=Todd|title=Higher plant cellulose synthase|journal=Genome Biology|date=2000|volume=1|pages=3001|doi=10.1186/gb-2000-1-4-reviews3001|url=http://genomebiology.com/2000/1/4/REVIEWS/3001/ref}}</ref> <ref>{{cite journal|last1=Lei, Li, Gu|first1=L, S, Y|title=Cellulose synthase complexes: composition and regulation|journal=Frontiers of Plant Science|date=2012|volume=3|pages=75|doi=10.3389/fpls.2012.00075|url=http://journal.frontiersin.org/Journal/10.3389/fpls.2012.00075/full}}</ref>.  Although important for plants, it is also synthesized by most algae, some bacteria, and some animals <ref name=Nakashima>{{cite journal|last1=Nakashima, Yamada, Satou, Azuma, Satoh|first1=K, L, Y, J, N|title=The evolutionary origin of animal cellulose synthase|journal=Development Genes and Evolution|date=2004|volume=26|pages=2996-3009|pmid=14740209|url=http://www.ncbi.nlm.nih.gov/pubmed/14740209}}</ref> <ref name=Yin>{{cite journal|last1=Yin, Huang, Xu|first1=Y, J, Y|title=The cellulose synthase superfamily in fully sequenced plants and algae|journal=BMC Plant Biology|date=2009|volume=9|page=99|doi=10.1186/1471-2229-9-99|url=http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3091534/}}</ref> <ref name=Sethaphong>{{cite journal|last1=Sethaphong, Haigler, Kubicki, Zimmer, Bonetta, DeBolt, Yinling|first1=L, CH, JD, J, D S, IG|title=Tertiary model of a plant cellulose synthase|journal=Proceedings of the National Academy of Sciences|date=2013|volume=110|pages=7512-7517|doi=10.1073/pnas.1301027110|url=http://www.ncbi.nlm.nih.gov/pubmed/23592721}}</ref><ref name=Li>{{cite journal|last1=Li, Lei, Gu|first1=S, L, Y|title=Functional analysis of complexes with mixed primary and secondary cellulose synthases|journal=Plant Signaling and Behavior|date=2012|volume=8|page=23179|url=http://www.pubfacts.com/detail/23299322/Functional-analysis-of-complexes-with-mixed-primary-and-secondary-cellulose-synthases.}}</ref>.  Worldwide, 2 × 1011 tons of cellulose microfibrils are produced <ref name=Lieth>{{cite book|last1=Lieth|first1=H|title=Measurement of calorific values. Primary productivity of the biosphere|date=1975|publisher=Springer|location=New York|pages=119-129|url=http://link.springer.com/book/10.1007/978-3-642-80913-2}}</ref>, which serves as a critical source of renewable biofuels and other biological-based products, such as lumber, fuel, fodder, paper and cotton <ref name=Olek /><ref name=Cutler>{{cite journal|last1=Cutler, Somerville|first1=S, C|title=Cellulose synthesis: Cloning in silico|journal=Current Biology|date=1997|volume=7|pages=108-111|doi=10.1016/S0960-9822(06)00050-9|url=http://www.researchgate.net/publication/222946544_Cellulose_synthesis_Cloning_in_silico}}</ref>.
+Purpose of cellulose
+These [[microfibrils]] are made on the surface of cell membranes to reinforce cells walls, which has been researched extensively by plant biochemists and cell biologist because 1) they regulate cellular morphogenesis and 2) they serve alongside many other constituents (i.e. [[lignin]], [[hemicellulose]], [[pectin]]) in the cell wall as a strong structural support and cell shape. <ref name=Cutler>{{cite journal|last1=Cutler, Somerville|first1=S, C|title=Cellulose synthesis: Cloning in silico|journal=Current Biology|date=1997|volume=7|pages=108-111|doi=10.1016/S0960-9822(06)00050-9|url=http://www.researchgate.net/publication/222946544_Cellulose_synthesis_Cloning_in_silico}}</ref>.  Without these support structures, cell growth would cause a cell to swell and spread in all directions, thus losing its shape viability <ref name=Hogetsu>{{cite journal|last1=Hogetsu, Shibaoka|first1=T, H|title=Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum.|journal=Planta|date=1978|volume=140|pages=445-449|doi=10.1007/BF00389374}}</ref>
+Cellulose synthase structure
+         Plant cellulose synthases belong to the family of [[glycosyltransferases]], which are proteins involved in the biosynthesis and hydrolysis of the bulk of earth’s biomass <ref name=Campbell>{{cite journal|last1=Campell, Davies, Bulone, Henrissat|first1=JA, GJ, V, BA|title=. Classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities|journal=Biochemistry|date=1997|volume=326|pages=929-939|pmid=PMC1219098|url=http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1219098/}}</ref>.  Cellulose is synthesized by a large cellulose synthase complexes (CSCs), which are comprised of synthase protein [[isoform]] (CesA) that are arranged into a unique hexagonal structure known as a “particle rosette” 50 nm wide and 30-35 nm tall <ref name=Giddings>{{cite journal|last1=Giddings, Brower, Staehelin|first1=TH, DL, LA|title=formation of cellulose fibrils in primary and secondary walls|journal=Journal of Cellular Biology|date=1980|volume=84|pages=327-339}}</ref><ref name=Bowling>{{cite journal|last1=Bowling, Brown|first1=AJ, RM Jr|title=The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants|journal=Protoplasma|date=2008|volume=233|pages=115-127}}</ref> (Giddings et al. 1980, Bowling and Brown 2008, Yin et al. 2009).  There are more than 20 of these full-length [[integral membrane proteins]], each of which is around 1000 [[amino acids]] long (Olek et al. 2014, Richmond 2000). These rosettes, formerly known as granules, were first discovered in 1972 by electron microscopy in green algae species ''[[Cladophora]]'' and ''[[Chaetomorpha]]'' (Robinson et al. 1972).  Solution [[x-ray scattering]] have shown that CesAs are at the surface of a plant cell and are elongated monomers with a two catalytic [[domains]] that fuse together into [[dimers]].  The center of the dimers is the main point of catalytic activity. Since cellulose is made in all cell walls, CesA proteins are present in all tissues and cell types of plants.  Nonetheless, there are different types of CesA, some tissue types may have varying concentrations of one over another.  For example, the AtCesA1 (RSW1) protein is involved in the biosynthesis of primary cell walls throughout the whole plant while the AtCesA7 (IRX3) protein is only expressed in the stem for secondary cell wall production (Richmond 2000).
+Cellulose synthase activity
+           Cellulose biosynthesis is the process during which separate homogeneous β-1,4-glucan chains, ranging from 2,000 to 25,000 glucose residues in length, are synthesized and then immediately hydrogen bond with one another to form rigid crystalline arrays, or microfibrils.  Microfibrils in the primary cell wall are approximately 36 chains long while those of the secondary cell wall are much larger, containing up to 1200 β-1,4-glucan chains (Cuter and Somerville 1997, Richmond 2000).  Uridine diphosphate-glucose (UDP), which is produced by the enzyme sucrose synthase (SuSy) that produces and transports UDP-glucose to the [[plasma membrane]] is the substrate used by cellulose synthase to produce the glucan chains.  (Heath 1974, Olek et al. 2014).  The rate at which glucose residues are synthesized per one glucan chain ranges from 300-1000 glucose residues per minute, the higher rate being more prevalent in secondary wall particles, such as in the xylem.   (Paredez et al. 2006, Wightman et al. 2009)
+Supporting structures
+Microfibril synthesis is guided by cortical [[microtubules]], which lie beneath the plasma membrane of elongating cells, in that they form a platform on which the CSCs can convert glucose molecules into the crystalline chains. The microtubule–microfibril alignment hypothesis proposes that cortical microtubules, which lie beneath the plasma membrane of elongating cells, provide tracks for CSCs that convert glucose molecules into crystalline cellulose microfibrils (Green 1962).  The direct hypothesis postulates some types of direct linkage between CESA complexes and microtubules (Heath 1974).  Additionally, the KORRIGAN (KOR1) protein is thought to be a critical component of cellulose synthesis in that it acts cellulose at the plasma membrane-cell wall interface.  KOR1 interacts with a two specific CesA proteins, possibly by proof-reading and relieving stress created glucan chain synthesis by hydrolyzing disordered amorphous cellulose. (Mansoori et al. 2014)
+Environmental influences
+Cellulose synthesis activity is affected by many environmental stimuli, such as hormones, light, mechanical stimuli, nutrition, and interactions with the [[cytoskeleton]].  Interactions with these factors may influence cellulose deposition in that it affects the amount of substrate produced and the concentration and/or activity of CSCs in the plasma membrane.
+Literature Cited
+-Bowling A.J., Brown R.M. Jr. 2008. The cytoplasmic domain of the cellulose-synthesizing complex in vascular plants. Protoplasma 233: 115–127.
+-Campbell J.A., Davies G.J., Bulone V. Henrissat B. A. 1997. classification of nucleotide-diphospho-sugar glycosyltransferases based on amino acid sequence similarities. Biochemistry 326: 929–939.
+-Cutler, S. and C. Somerville. 1997. Cellulose synthesis: Cloning in silico. Current Biology 7: 108-111.
+-Giddings, T.H., D.L. Brower, and L.A. Staehelin. 1980. Visualization of particle complexes in the membrane of Micrastrias denticulata associated with the formation of cellulose fibrils in primary and secondary walls. Journal of Cellular Biology 84: 327–339
+-Green, P. B. 1962. Mechanism for plant cellular morphogenesis. Science 138, 1404–1405.
+-Haigler, C. H., Ivanova-Datcheva, M., Hogan, P. S., Salnikov, V. V., Hwang, S., Martin, K., and Delmer, D. P. 2001. Carbon partitioning to cellulose synthesis. Plant Molecular Biology 47: 29–51.
+- Heath, I. B. 1974. A unified hypothesis for the role of membrane bound enzyme complexes and microtubules in plant cell wall synthesis. Journal of  Theoretical Biology  48:  445–449.
+-Hogestsu, T. and H. Shibaoka. 1978. Effects of colchicine on cell shape and on microfibril arrangement in the cell wall of Closterium acerosum. Planta 140: pp. 15–18
+-Li, S., L. Lei, and Y. Gu. 2012. Functional analysis of complexes with mixed primary and secondary cellulose synthases. Plant Signaling & Behavior 8: e23179.
+-Lei, L., S. Li, and Y. Gu. 2012. Cellulose synthase complexes: composition and regulation. Frontiers of Plant Science 3: 75.
+-Lieth, H. 1975. Measurement of calorific values. Primary productivity of the biospher. Eds. H. Lieth and R. H. Whittaker. Springer, New York. 119-129.
+-Mansoori, N., J. Timmers, T. Desprez, C.L.A. Kamei, D.C.T Dees, J-P. Vinken, R.G.F. Visser, H. Hoefte, S. Vernhettes, L.M. Trindade. 2014. KORRIGAN1 interacts specifically with integral components of the cellulose synthase machinery. PLoS ONE 9: e112387.
+-Nakashima K1, Yamada L, Satou Y, Azuma J, Satoh N. 2004. The evolutionary origin of animal cellulose synthase. Development Genes and Evolution 214: 81-88.
+-Olek, A.T, C. Rayon, L. Makowski, H.R. Kim, P. Ciesielski, J. Badger, L.N. Paul, S. Ghosh, D. Kihara, M. Crowley, M.E. HImmel, J.T. Bolin, and N.C. Carpita.  2014. The structure of the catalytic domain of a plant cellulose synthase and its assembly into dimers. The Plant Cell 26: 2996-3009.
+- Paredez, A. R., Somerville, C. R., and Ehrhardt, D. W. 2006. Visualization of cellulose synthase demonstrates functional association with microtubules. Science 312: 1491–1495.
+-Richmond, T. 2000. Higher plant cellulose synthase. Genome Biology 1: 3001-3001.6.
+-Robinson, D. G., White, R. K., and Preston, R. D. (1972). Fine structure of swarmers of Cladophora and Chaetomorpha. III. Wall synthesis and development. Planta 107, 131–144.
+-Sethaphong, L., C.H. Haigler, J.D. Kubicki, J. Zimmer, D. Bonetta, S. DeBolt, I.G. Yingling. 2013. Tertiary model of a plant cellulose synthase.  Proceedings of the National Academy of Sciences 110: 7512-7517.
+-Wightman, R., and Turner, S. R. 2008. The roles of the cytoskeleton during cellulose deposition at the secondary cell wall. Plant Journal 54: 794–805.
+-Yin, Y., J. Huang, and Y. Xu. 2009. The cellulose synthase superfamily in fully sequenced plants and algae. BMC Plant Biology 9: 99.
 {{enzyme
 | name=cellulose synthase (UDP-forming)