Plant matrix metalloproteinases are metalloproteins and zinc enzymes found in plants.

Matrix Metalloproteinase

Matrix metalloproteinases (MMPs) are zinc endopeptidases, commonly called metzincins. MMP enzymes represent an ancient family of proteins with major similarities in genetic make-up that are present in a range of diverse organisms from unicellular bacteria to multicellular vertebrates and invertebrates. The superfamily is distinguished due to its motif consisting of three histidines bonded to zinc at the catalytic site.

The metzincins are divided into four smaller families: (I don’t really know what these are so I went looking for information…not sure I don’t have to keep looking but for now)

• seralysins, 
  • Serralysin (EC 3.4.24.40, Pseudomonas aeruginosa alkaline proteinase, Escherichia freundii proteinase, Serratia marcescens extracellular proteinase, Serratia marcescens metalloproteinase, Pseudomonas aeruginosa alk. protease, Serratia marcescens metalloprotease) is an enzyme.^{[Morihara K, Tsuzuki H, Oka T (March 1968). “Comparison of the specificities of various neutral proteinases from microorganisms”. Archives of Biochemistry and Biophysics. 123 (3): 572–88. doi:10.1016/0003-9861(68)90179-3. PMID 4967801][Morihara K, Tsuzuki H, Oka T (June 1973). “On the specificity of Pseudomonas aeruginosa alkaline proteinase with synthetic peptides”. Biochimica et Biophysica Acta (BBA) – Enzymology. 309 (2): 414–29. doi:10.1016/0005-2744(73)90040-5. PMID 4199986.][Nakajima M, Mizusawa K, Yoshida F (May 1974). “Purification and properties of an extracellular proteinase of psychrophilic Escherichia freundii”. European Journal of Biochemistry. 44 (1): 87–96. doi:10.1111/j.1432-1033.1974.tb03460.x. PMID 4212288][Decedue CJ, Broussard EA, Larson AD, Braymer HD (August 1979). “Purification and characterization of the extracellular proteinase of Serratia marcescens”. Biochimica et Biophysica Acta (BBA) – Enzymology. 569 (2): 293–301. doi:10.1016/0005-2744(79)90065-2. PMID 383155][ Doerr M, Traub WH (May 1984). “Purification and characterization of two Serratia marcescens proteases”. Zentralblatt für Bakteriologie, Mikrobiologie, und Hygiene. Series A, Medical Microbiology, Infectious Diseases, Virology, Parasitology. 257 (1): 6–19. PMID6380155][ Nakahama K, Yoshimura K, Marumoto R, Kikuchi M, Lee IS, Hase T, Matsubara H (July 1986). “Cloning and sequencing of Serratia protease gene”. Nucleic Acids Research. 14 (14): 5843–55. doi:10.1093/nar/14.14.5843. PMC311595. PMID3016665][Dahler GS, Barras F, Keen NT (October 1990). “Cloning of genes encoding extracellular metalloproteases from Erwinia chrysanthemi EC16”. Journal of Bacteriology. 172 (10): 5803–15. doi:10.1128/jb.172.10.5803-5815.1990. PMC 526898. PMID 2211513][ Okuda K, Morihara K, Atsumi Y, Takeuchi H, Kawamoto S, Kawasaki H, Suzuki K, Fukushima J (December 1990). “Complete nucleotide sequence of the structural gene for alkaline proteinase from Pseudomonas aeruginosa IFO 3455”. Infection and Immunity. 58 (12): 4083–8. doi:10.1128/IAI.58.12.4083-4088.1990. PMC313780. PMID2123832]} 
    • This enzyme catalyses the following chemical reaction
      • Preferential cleavage of bonds with hydrophobic residues in P1′
    • This extracellular endopeptidase is present in Pseudomonas aeruginosa, Escherichia freundii, Serratia marcescens and Erwinia chrysanthemi.
  • Serratiopeptidase (Serratia E-15 protease, also known as serralysin, serrapeptase, serratiapeptase, serratia peptidase, serratio peptidase, or serrapeptidase) is a proteolytic enzyme (protease) produced by non-pathogenic enterobacterium Serratia sp. E-15, now known as Serratia marcescens ATCC 21074.^{[Nakahama K, Yoshimura K, Marumoto R, Kikuchi M, Lee IS, Hase T, Matsubara H (July 1986). “Cloning and sequencing of Serratia protease gene”. Nucleic Acids Research. 14 (14): 5843–55. doi:10.1093/nar/14.14.5843. PMC 311595. PMID 3016665]} 
    • This microorganism was originally isolated in the late 1960s from silkworm Bombyx mori L. (intestine).^{[The preparation and some uses of the protease are described in US patent 3792160, Isono M, Kazutaka M, Kodama R, Tomoda K, Miyata K, “Method of treating inflammation and composition therefor”, issued 1974-02-12, assigned to Takeda Chemical Industries Ltd.. The enzyme was also described by Miyata K, Maejima K, Tomoda K, Isono M (1970). “Serratia protease. Part I. Purification and general properties of the enzyme”. Agricultural and Biological Chemistry. 34 (2): 310–318. and the strain of bacteria producing serratiopeptidase has been deposited with the American Type Culture Collection as strain ATCC 21074. (For online information about ATCC 21074, enter 21074 on the ATCC/LGC search page)]} 
    • Serratiopeptidase is present in the silkworm intestine and allows the emerging moth to dissolve its cocoon. Serratiopeptase is produced by purification from culture of Serratia E-15 bacteria. It is a member of the Peptitase M10B (Matrixin) family.
  • Serratia is a genus of Gram-negative, facultatively anaerobic, rod-shaped bacteria of the family Yersiniaceae.^{[Khanna, Ashish; Khanna, Menka; Aggarwal, Aruna (February 2013). “Serratia Marcescens- A Rare Opportunistic Nosocomial Pathogen and Measures to Limit its Spread in Hospitalized Patients”. Journal of Clinical and Diagnostic Research. 7 (2): 243–246. doi:10.7860/JCDR/2013/5010.2737. ISSN 2249-782X. PMC 3592283. PMID 23543704]} 
    • According to the List of Prokaryotic names with Standing Nomenclature (LPSN), there are currently 19 species of Serratia that are credibly published with accurate names as of 2020: S. aquatilis, S. entomophila, S. ficaria, S. fonticola, S. grimesii, S. liquefaciens, S. marcescens, S. microhaemolytica, S. myotis, S. nematodiphila, S. odoriferae, S. oryzae, S. plymuthica, S. proteamaculans, S. quinivorans corrig, S. rubidaea, S. symbiotica, S. ureilytica, S. vespertilionis.^{[“Genus: Serratia”. lpsn.dsmz.de. Retrieved 29 April 2020.]} 
      • They are typically 1–5 μm in length, do not produce spores,^{[“Enterobacteriaceae” (PDF). Louisiana Department of Health. Retrieved 29 April 2020.]} 
      • and can be found in water, soil, plants, and animals.^{[Fusco, Vincenzina; Abriouel, Hikmate; Benomar, Nabil; Kabisch, Jan; Chieffi, Daniele; Cho, Gyu-Sung; Franz, Charles M. A. P. (1 January 2018), Grumezescu, Alexandru Mihai; Holban, Alina Maria (eds.), “Chapter 10 – Opportunistic Food-Borne Pathogens”, Food Safety and Preservation, Academic Press, pp. 269–306, ISBN 978-0-12-814956-0]} 
    • Some members of this genus produce a characteristic red pigment, prodigiosin, and can be distinguished from other members of the order Enterobacterales by their unique production of three enzymes: DNase (nucA), lipase, and gelatinase (serralysin). Serratia was thought to be a harmless environmental bacteria until it was discovered that the most common species in the genus, S. marcescens, is an opportunistic pathogen of many animals, including humans.^{[Khanna, Ashish; Khanna, Menka; Aggarwal, Aruna (February 2013). “Serratia Marcescens- A Rare Opportunistic Nosocomial Pathogen and Measures to Limit its Spread in Hospitalized Patients”. Journal of Clinical and Diagnostic Research. 7 (2): 243–246. doi:10.7860/JCDR/2013/5010.2737. ISSN 2249-782X. PMC 3592283. PMID 23543704]} 
    • In humans, S. marcescens is mostly associated with nosocomial, or hospital-acquired, infections, but can also cause urinary tract infections, pneumonia, and endocarditis.^{[Greenberg, Leo (November 1978). “Serratia Marcescens in Human Affairs”. Drug Intelligence & Clinical Pharmacy. 12 (11): 674–679. doi:10.1177/106002807801201106. ISSN 0012-6578. PMID 10297265. S2CID 25400762]} 
    • S. marcescens is frequently found in showers, toilet bowls, and around wetted tiles as a pinkish to red biofilm but only causes disease in immunocompromised individuals. Aside from S marcescens, some rare strains of the Serratia species S. plymuthica, S. liquefaciens, S. rubidaea, and S. odoriferae have been shown to cause infection such as osteomyelitis and endocarditis.^{[“Serratia: Background, Pathophysiology, Epidemiology”. 11 November 2019.]}

• astacins, 
  • Astacins are a family of multidomain metalloendopeptidases which are either secreted or membrane-anchored.^{[Gomis-Rüth FX, Trillo-Muyo S, Stöcker W (October 2012). “Functional and structural insights into astacin metallopeptidases”. Biological Chemistry. 393 (10): 1027–41. doi:10.1515/hsz-2012-0149. hdl:10261/87872. PMID 23092796. S2CID 11098025.]} 
  • These metallopeptidases belong to the MEROPS peptidase family M12, subfamily M12A (astacin family, clan MA(M)). The protein fold of the peptidase domain for members of this family resembles that of thermolysin, the type example for clan MA and the predicted active site residues for members of this family and thermolysin occur in the motif HEXXH.^{[ Rawlings ND, Barrett AJ (1995). “Evolutionary families of metallopeptidases”. Methods in Enzymology. 248: 183–228. doi:10.1016/0076-6879(95)48015-3. PMID7674922]}
  • The astacin family of metalloendopeptidases (EC 3.4.24.21) encompasses a range of proteins found in hydra to humans, in mature and developmental systems. Their functions include activation of growth factors, degradation of polypeptides, and processing of extracellular proteins.^{[Bond JS, Beynon RJ (July 1995). “The astacin family of metalloendopeptidases”. Protein Science. 4 (7): 1247–61. doi:10.1002/pro.5560040701. PMC 2143163. PMID 7670368]} The proteins are synthesised with N-terminal signal and pro-enzyme sequences, and many contain multiple domains C-terminal to the protease domain. They are either secreted from cells, or are associated with the plasma membrane.
  • The astacin molecule adopts a kidney shape, with a deep active-site cleft between its N- and C-terminal domains. The zinc ion, which lies at the bottom of the cleft, exhibits a unique penta-coordinated mode of binding, involving 3 histidine residues, a tyrosine and a water molecule (which is also bound to the carboxylate side chain of Glu93).^{[ Gomis-Rüth FX, Stöcker W, Huber R, Zwilling R, Bode W (February 1993). “Refined 1.8 A X-ray crystal structure of astacin, a zinc-endopeptidase from the crayfish Astacus astacus L. Structure determination, refinement, molecular structure and comparison with thermolysin”. Journal of Molecular Biology. 229 (4): 945–68. doi:10.1006/jmbi.1993.1098. PMID8445658]} 
  • The N-terminal domain comprises 2 alpha-helices and a 5-stranded beta-sheet. The overall topology of this domain is shared by the archetypal zinc-endopeptidase thermolysin. Astacin protease domains also share common features with serralysins, matrix metalloendopeptidases, and snake venom proteases; they cleave peptide bonds in polypeptides such as insulin B chain and bradykinin, and in proteins such as casein and gelatin; and they have arylamidase activity.^{[Bond JS, Beynon RJ (July 1995). “The astacin family of metalloendopeptidases”. Protein Science. 4 (7): 1247–61. doi:10.1002/pro.5560040701. PMC 2143163. PMID 7670368]}
• adamalysins (ADAMs), and
  • ADAMs (short for a disintegrin and metalloproteinase) are a family of single-pass transmembrane and secreted metalloendopeptidases.^{[Brocker, C; Vasiliou, V; Nebert, DW (October 2009). “Evolutionary divergence and functions of the ADAM and ADAMTS gene families”. Human Genomics. 4 (1): 43–55. doi:10.1186/1479-7364-4-1-43. PMC 3500187. PMID 19951893][Wolfsberg TG, Straight PD, Gerena RL, et al. (1995). “ADAM, a widely distributed and developmentally regulated gene family encoding membrane proteins with a disintegrin and metalloprotease domain”. Dev. Biol. 169 (1): 378–383. doi:10.1006/dbio.1995.1152. PMID 7750654]} 
    • All ADAMs are characterized by a particular domain organization featuring a pro-domain, a metalloprotease, a disintegrin, a cysteine-rich, an epidermal-growth factor like and a transmembrane domain, as well as a C-terminal cytoplasmic tail.^{[“ADAM, cysteine-rich (IPR006586)”. InterPro. Retrieved 18 February 2016.]} 
    • Nonetheless, not all human ADAMs have a functional protease domain, which indicates that their biological function mainly depends on protein–protein interactions. Those ADAMs which are active proteases are classified as sheddases because they cut off or shed extracellular portions of transmembrane proteins.^{[Edwards DR, Handsley MM, Pennington CJ (October 2008). “The ADAM metalloproteinases”. Mol. Aspects Med. 29 (5): 258–89. doi:10.1016/j.mam.2008.08.001. PMC 7112278. PMID 18762209]} 
      • For example, ADAM10 can cut off part of the HER2 receptor, thereby activating it.^{[Liu, P.C.; et al. (2006). “Identification of ADAM10 as a major source of HER2 ectodomain sheddase activity in HER2 overexpressing breast cancer cells”. Cancer Biology and Therapy. 5 (6): 657–664. doi:10.4161/cbt.5.6.2708. PMID 16627989.]} 
    • ADAM genes are found in animals, choanoflagellates, fungi and some groups of green algae. Most green algae and all land plants likely lost ADAM proteins.^{[Souza J, Lisboa A, Santos T, Andrade M, Neves V, Teles-Souza J, Jesus H, Bezerra T, Falcão V, Oliveira R, Del-Bem L (2020). “The evolution of ADAM gene family in eukaryotes”. Genomics. 112 (5): 3108–3116. doi:10.1016/j.ygeno.2020.05.010. PMID 32437852. S2CID 218832838]}
    • ADAMs are categorized under the EC 3.4.24.46 enzyme group, and in the MEROPS peptidase family M12B.^{[“ADAM, cysteine-rich (IPR006586)”. InterPro. Retrieved 18 February 2016]} 
    • The terms adamalysin and MDC family (metalloproteinase-like, disintegrin-like, cysteine rich) have been used to refer to this family historically.^{[Blobel, CP (22 August 1997). “Metalloprotease-disintegrins: links to cell adhesion and cleavage of TNF alpha and Notch”. Cell. 90 (4): 589–92. doi:10.1016/s0092-8674(00)80519-x. PMID 9288739. S2CID 17710705]}
  • Adamalysin (EC 3.4.24.46, Crotalus adamanteus metalloendopeptidase, proteinase I and II, Crotalus adamanteus venom proteinase II, adamalysin II) is an enzyme.^{[ Kurecki T, Laskowski M, Kress LF (November 1978). “Purification and some properties of two proteinases from Crotalus adamanteus venom that inactivate human alpha 1-proteinase inhibitor”. The Journal of Biological Chemistry. 253 (22): 8340–5. PMID 309470.]} 
    • This enzyme catalyses the following chemical reactionCleavage of Phe¹-Val, His⁵-Leu, His¹⁰-Leu, Ala¹⁴-Leu, Leu¹⁵-Tyr, and Tyr¹⁶-Leu of insulin B chain
    • This enzyme is present in the venom of the eastern diamondback rattlesnake (Crotalus adamanteus).
    • See also A disintegrin and metalloproteinase

• MMPs.

The MMP family is formed by twenty related zinc-dependent enzymes. They are noted for having the ability to degrade extracellular matrix proteins, such as collagens, laminin, and proteoglycans. These calcium- and zinc-dependent proteases are activated at neutral pH and twenty-three have been found present in mammalian cells. Plant MMPs show structural similarity to MMPs found in mammals, such as the presence of an auto-regulatory cysteine switch domain and a zinc-binding catalytic domain.^[1]

MMPs are synthesized primarily by connective tissues and have a large contribution to the initial events of tissue degradation. There are three major groups of the MMP family and each group has more than one distinct gene product that distinguishes them apart from one another on the immunological and biochemical criteria. Similar to that of induced fit by enzyme-substrate interactions, MMPs in the first group, called collagenases, have interstitial collagens. The second group, called gelatinases, degrade denatured collagens catalytically. The third group, called stromelysins, have the broadest proteolytic action and were originally confused as proteoglyconases. A less clearly described group of MMPs is the PUMP. Its RNA was taken from stromal cells in human breast carcinomas. Based on the PUMP sequence and functionality of carcinomas in the progression of malignancy, a new branch of the MMP family could have been discovered.^[2]

Extracellular Matrix

The most basic description of the plant extracellular matrix (ECM) is the cell wall, but it is actually the cell surface continuum that includes a variety of proteins with major roles in plant growth, development, and response. The ECM is composed of the primary and secondary cell walls, along with the intercellular gap between its neighboring cells. The ECM has a functional structure, along with aid in the regulation of turgor, which acts as a protective barrier and communicates with other cells using signaling pathways. In mammalian animals, extracellular matrix metalloproteinases (MMPs) modify the ECM to play significant roles in biological processes. The important role of MMP function in the extracellular matrix modification and subsequent mammalian development and signaling suggests that further study on the structure and function of these extracellular metalloproteinases may reveal new aspects of ECM modification in plant development.^[3]

Plant MMPs

All known MMPs have been studied in vertebrates; it is hypothesized that they are involved in remodeling connective tissue during development and healing. Current advances are being made in the field of Biochemistry, which will further analyze MMP-ECM interaction and their effects during plant development, stress induction, and xylem–phloem differences. SMEP1, soybean metalloendoproteinase 1, has been sequenced and characterized. It is noted that several unique divergences are in SMEP1 from that of the normal MMP family. For example, SMEP1 is said to have a free cysteine at position 94, a non-homologous insert from V103 to S121, a free sulfhydryl group, and the complete lack of the aspartate that is found in all of the other MMPs.^[4]

Studies of plant MMPs

Protein inhibitors of proteases, are present in plants, animals, and microorganisms. They are ubiquitous in nature and have a small molecular mass ranging from four to twenty-five kilo-Daltons. Different types of protease inhibition are directed toward a single class of protease. There are few reports on natural inhibitors of metalloproteinases. The metalloproteinase inhibitors (MPIs) can prevent unwanted proteolysis by denaturing their target proteases through non-competitive inhibition at an allosteric site. Five novel Lupinus albus MPIs were found and constitute the first reported protein inhibitors of metalloproteinases in plants and the first reported plant peptide inhibitors against a matrixin proteinase.^[5]

MtMMPL1, a Medicago truncatula nodulin gene identified by transcriptomics, is said to represent a novel and specific marker for root and nodule infection by Sinorhizobium meliloti. The possible role in the nitrogen-fixing symbiosis of a nodulin gene was investigated. The immune response of the plant to the alterations in the exopolysaccharides (EPSs) and lipopolysaccharides (LPSs) of various rhizobia led to the formation of enlarged infection threads (ITs) with thickened cell walls, which is often associated with plant defense reactions, and to the production of ineffective nodules in their plant host. Even though its precise role is classified as unknown, MTMMPL1 is noted as the first member of this biologically important protein family with a clear function in plant-microbe symbiotic associations.^[6]

At2-MMP from arabidopsis was found in leaves and roots of young arabidopsis and leaves, roots, and inflorescences of mature flowering plants showing strong increase of transcript abundance with aging. In the leaves, the MMP gene was expressed in the phloem, developing xylem elements, neighboring mesophyll cell layers, and epidermal cells. The flowers were noted as having the gene in pistils, ovules, and receptacles. It was concluded that the At2-MMP has a physiological role in mature aging tissue and the possibility of being involved in plant senescence.^[7]

The fungus Chondrostereum purpureum, the causal agent of silver leaf, was grown in liquid culture and agar, which caused it to secrete extracellular proteinases into the medium. The fluid dialysed by the activation of metal ions, which confirmed the presence of metalloproteinases. The silverleaf disease is a basidiomycete pathogenic on a wide range of host plants. The most notable host plant species include pomaceous and stone fruit species which are substantial for New Zealand’s economy. Cations, such as copper, zinc, and cobalt, are all inhibitory for the control of extract and stimulatory for EDTA-dialysed extract, which could possibly make the processes native cofactors. The amount of proteinases could be variable to the duration of the infection’s presence. Activity was found throughout the infected zone and not just the wound site; therefore, fungal growth and proteinase activity have a direct relationship. Even though zinc-binding metalloproteinases have been found to aid processes such as protein turnover and embryogenesis, it is still unclear as to the role they play in plants. To try to better understand MMPs’ role in plant tissue, the SMEP1 is cloned and analyzed using a polymerase chain reaction (PCR) and the rapid amplification of cDNA ends (RACE) reaction. It was found only to be present in mature leaves, which suggest that SEMP1 may play an important role in tissue modeling.^[8]

References

Notes

1. ^ Cao, J. & Zucker, S. (n.d.). Introduction to the MMP and TIMP families (structures, substrates) and an overview of diseases where MMPs have been incriminated. Biology and chemistry of matrix metalloproteinases (MMPs). Retrieved from http://www.abcam.com/index.html?pageconfig=resource&rid=11034
2. ^ Murphy, G., Murphy, G., & Reynolds, J. (1991). The origin of matrix metalloproteinases and their familial relationships. Federation of European Biochemical Societies, 289 (1), 4-7. doi:10.1016/0014-5793(91)80895-A
3. ^ Flinn, B. (2008). Review: Plant extracellular matrix metalloproteinases. Functional Plant Biology, 35, 1183-1193.
4. ^ McGeehan, G., Burkhart, W., Anderegg, R., Becherer, J. D., Gillikin, J. W., & Graham, J. S. (1992). Sequencing and Characterization of the Soybean Leaf Metalloproteinase. Plant Physiol., 99, 1179-1183.
5. ^ Carrilho, D., Duarte, I., Francisco, R., Ricardo, C., & Duque-Magalhaes, M. (2009). Discovery of Novel Plant Peptides as Strong Inhibitors of Metalloproteinases. Protein & Peptide Letters, 16, 543-551.
6. ^ Combier, J., Vernie, T., Billy, F., Yahyaoui, F., Mathis, R., & Gamas, P. (2007). The MtMMPL1 Early Nodulin is a novel member of the matrix metalloproteinase family with a role in Medicago truncatula infection by Sinorhizobium meliloti. Plan Physiology, 144, 703-716.
7. ^ Golldack, D., Popova, O., & Dietz, K. (2002). Mutation of the Matrix Metalloproteinase At2-MMP Inhibits Growth and Causes Late Flowering and Early Senescence in Arabidopsis. The Journal of Biological Chemistry, 277 (7) 5541-5547.
8. ^ . Graham, J. S., Xiong, J., & Gillikin, J. W. (1991). Purification and Developmental Analysis of a Metalloendoproteinase from the Leaves of Glycine max. Plant Physiol., 97, 786-792

Bibliography

• Cao, J. & Zucker, S. (n.d.). Introduction to the MMP and TIMP families (structures, substrates) and an overview of diseases where MMPs have been incriminated. Biology and chemistry of matrix metalloproteinases (MMPs). Retrieved from http://www.abcam.com/index.html?pageconfig=resource&rid=11034
• Murphy, G., Murphy, G., & Reynolds, J. (1991). The origin of matrix metalloproteinases and their familial relationships. Federation of European Biochemical Societies, 289 (1), 4-7. doi:10.1016/0014-5793(91)80895-A
• Flinn, B. (2008). Review: Plant extracellular matrix metalloproteinases. Functional Plant Biology, 35, 1183-1193.
• McGeehan, G., Burkhart, W., Anderegg, R., Becherer, J. D., Gillikin, J. W., & Graham, J. S. (1992). Sequencing and Characterization of the Soybean Leaf Metalloproteinase. Plant Physiol., 99, 1179-1183.
• Carrilho, D., Duarte, I., Francisco, R., Ricardo, C., & Duque-Magalhaes, M. (2009). Discovery of Novel Plant Peptides as Strong Inhibitors of Metalloproteinases. Protein & Peptide Letters, 16, 543-551.
• Combier, J., Vernie, T., Billy, F., Yahyaoui, F., Mathis, R., & Gamas, P. (2007). The MtMMPL1 Early Nodulin is a novel member of the matrix metalloproteinase family with a role in Medicago truncatula infection by Sinorhizobium meliloti. Plan Physiology, 144, 703-716.
• Golldack, D., Popova, O., & Dietz, K. (2002). Mutation of the Matrix Metalloproteinase At2-MMP Inhibits Growth and Causes Late Flowering and Early Senescence in Arabidopsis. The Journal of Biological Chemistry, 277 (7) 5541-5547.
• Graham, J. S., Xiong, J., & Gillikin, J. W. (1991). Purification and developmental Analysis of a Metalloendoproteinase from the Leaves of Glycine max. Plant Physiol., 97, 786-792.
• Ao, C., Li, A., Elzaawely, A., & Tawata, S. (2008). MMP-13 Inhibitory Activity of Thirteen Selected Plant Species from Okinawa. International Journal of Pharmacology, 4 (3), 202-207.

Categories: 

• Metalloproteins
• Zinc enzymes

From Wikipedia where this page was last updated September 19, 2021