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This Sandbox is Reserved from January 19, 2016, through August 31, 2016 for use for Proteopedia Team Projects by the class Chemistry 423 Biochemistry for Chemists taught by Lynmarie K Thompson at University of Massachusetts Amherst, USA. This reservation includes Sandbox Reserved 425 through Sandbox Reserved 439.

Penicillin binding protein/lactivicin (inhibitor) (2jch)^[1]

by Tyler Carpenter, Samuel Pierce, Hyunjoon Choi, Anton El Khoury and Tiankai Zhang

Student Projects for UMass Chemistry 423 Spring 2016

1 Introduction
2 Overall Structure
3 Binding Interactions
4 Additional Features
5 Quiz Question 1
6 See Also
7 Credits
8 References

Introduction

Every bacteria wants to live. Every bacteria wants to reproduce. To achieve both, bacteria need some sort of protection that will maintain the structure inside and will protect it from outside dangers. This protection is called cell wall, that primarily consists of a polymer that is called peptidoglycan. This compound can be synthesized only with the help of penicillin binding proteins (PBPs) , which are the target of this article (the name basically comes from a way it was discovered). PBP serves as a catalyst in the final stages of peptidoglycan synthesis, transglycosylation and transpeptidation in particular.^[2] Although there are multiple types of PBPs, they all bind penicillin (however, with different affinities) and this is what is important for this article.

As the bacteria infiltrates the organism, it becomes necessary to somehow destroy it. One way is to to break this cell wall. To achieve this, the penicillin is introduced to the bacteria that later reacts with PBPs (using β-lactam ring ), preventing it from catalyzing the formation of a peptidoglycan and, as a result, stops the formation of a cell wall. However, many pathogenic bacteria have evolved a way to mutate themselves to be immune to various drugs that contain this β-lactam rings. What happens is that bacterium produces enzyme, called that cleaves the β-lactam ring on a penicillin and thus preventing it from reacting with PBPs. To solve this problem, the new drug, called, lactivicin was developed that contains gamma-lactone rings and cycloserine as substitutions to β-lactam. So far, it has proved to be an efficient antibiotic. It successfully binds to PBPs and prevents cell wall from forming.

Recently, an analog of lactivicin, phenoxylactivicin (PLTV) was developed and is discussed in this article.

The complex of the PBP with is shown on the picture.

Picture on the right is displayed as N-terminus to C-termiunus Rainbow for. The coloring goes as shown on the sample:

Amino Terminus Carboxy Terminus

Overall Structure

Penicillin Binding Proteins have specific structures and designs that promote allow the binding of Penicillin and other antibiotics. One of the enzymes within the PBP family is . This enzyme is responsible for the link between two chains in the peptidoglycan network ^[3]. DA-DA peptidase’s structure contains a serine in the active site. Ser 62 is used to bind a peptide strand which would then link to another strand of the network, and this is the site where penicillin binds and inhibits the protein. This enzyme is split into two sections, which will be referred to as the North and South regions. The North Region contains both the carboxyl and amino termini, two α-helices, and a nine-stranded antiparallel β-sheet ^[4] This leads the Northern region of the enzyme to appear symmetrical. Both termini lead are connected to helices and then into β-strands. Inbetween the sets of strands the South region of the peptide is formed and this is strictly made out of helices. In the center of the two regions is where the Ser 62 active site resides, and this is also at the symmetrical center of the protein. The protein essentially forms a cupped hand, with the center of the palm being the active site, the bottom of the palm being a series of 8 or so helices, the knuckles being the β-strands, and the tips of the fingers being the two helices of the North region.

Binding Interactions

The final stages of the synthesis of peptidoglycan requires penicillin binding proteins. All bacterial cell walls are made of peptidoglycan and it is important to note that all bacteria have reactions that covalently link the first peptidoglycan between two polysaccharides. This reaction is catalyzed by transpeptidase enzymes which is inhibited by the beta-lactam. Penicillin binding protein binds to beta-lactam antibiotics because they are similar in chemical structure to the modular pieces that form the peptidoglycan. The amide bond is ruptured to form a covalent bond with the catalytic serine at the binding protein's active site. When the PBP form a stable covalent complex with the beta-lactam antibiotics, the cell dies due to PBP inactivation.
The beta-lactam area in most drugs resemble the D-Ala-D-Ala end of peptides to which the transpeptidase enzyme binds. At the DA-DA, there is a serine 62 which is used to bind peptide strands to other stands and this is also where penicillin binds and inhibits the protein. When the transpeptidase reaction takes place, the enzymes bind to the DA-DA end of the chain which results in one of the DA residues to be released and the enzyme attaches to the end of the peptide. Next, the closest peptidoglycan is covalently linked to the first peptidoglycan which forms a crosslink between the two polysaccharides. Almost every bacterium has PBP genes but most enzymes are inhibited by the beta-lactams. The enzymes become inactive due to the drugs binding tightly to the active site and blocking the reaction.

Additional Features

Antibiotics resistance is the property of bacteria that have receive relatively low effectiveness by antibiotic. With the overproduction and overusing of antibiotics, more bacteria have low resistance to antibiotic are killed than the bacteria have high resistance. Under the evolutionary pressure, the remaining group of bacteria have relatively high resistance which means that the normal antibiotics have less effectiveness or do not have effectiveness anymore. As penicillin-binding proteins playing an important role at bacteria’s cell synthesis and β-lactams antibiotics inhibiting bacterial division by binding penicillin-binding proteins, antibiotics resistance also emerges to the penicillin-binding proteins and makes penicillin-binding proteins have low affinity for penicillins.
Normally, the bacteria produce the penicillin binding proteins with low penicillin-affinity by transformation, which is a kind of gene modification. Through this way, bacteria could have a relatively higher resistance to β-lactams antibiotics. But staphylococcus is a special case, it strengthens the drug resistance by two ways instead of gene exchange. By the raised dissociation constants for the non-covalent pre-acylation and the dropped penicillin-sensitive microscopic rate constant for acylation, staphylococcus enhance its own drug resistance.^[5]
And the solution to the penicillin binding proteins drug resistance could be semi-synthetic β-lactams. The mechanism is that semi-synthetic β-lactams have the alternative side chain compared to the normal penicillins and it will make penicillin binding proteins have the higher affinity to it and as a result the increasing drug resistance will be solved.^[6]

Quiz Question 1

The binding pocket for PTLV (all residues within 5Å of the molecule) is shown colored from most conserved to most variable.

Why are most of these residues highly conserved?
Would it be evolutionarily advantageous to mutate this binding pocket to prevent inhibition by PTLV? Explain.

See Also

Penicillin-binding protein
2y2g
2bg1
2fff
2jch

Credits

Introduction - Anton El Khoury
Overall Structure - Tyler Carpenter
Drug Binding Site - Hyunjoon Choi
Additional Features - Tiankai Zhang
Quiz Question 1 - Samuel Pierce

References

↑ Macheboeuf P, Fischer DS, Brown T Jr, Zervosen A, Luxen A, Joris B, Dessen A, Schofield CJ. Structural and mechanistic basis of penicillin-binding protein inhibition by lactivicins. Nat Chem Biol. 2007 Sep;3(9):565-9. Epub 2007 Aug 5. PMID:17676039 doi:10.1038/nchembio.2007.21

↑ Pinho MG, Kjos M, Veening JW. How to get (a)round: mechanisms controlling growth and division of coccoid bacteria. Nat Rev Microbiol. 2013 Sep;11(9):601-14. doi: 10.1038/nrmicro3088. PMID:23949602 doi:http://dx.doi.org/10.1038/nrmicro3088

↑ Goodsell, David. "Penicillin-binding Proteins." Penicillin-binding Proteins. May 2002. Web. 07 Apr. 2016.

↑ Kelly, J. A., and A. P. Kuzin. "3PTE." RCSB PDB. Web. 07 Apr. 2016.

↑ Fuda C, Suvorov M, Vakulenko SB, Mobashery S. The basis for resistance to beta-lactam antibiotics by penicillin-binding protein 2a of methicillin-resistant Staphylococcus aureus. J Biol Chem. 2004 Sep 24;279(39):40802-6. Epub 2004 Jun 28. PMID:15226303 doi:http://dx.doi.org/10.1074/jbc.M403589200

↑ Ohi N, Aoki B, Shinozaki T, Moro K, Noto T, Nehashi T, Okazaki H, Matsunaga I. Semisynthetic beta-lactam antibiotics. I. Synthesis and antibacterial activity of new ureidopenicillin derivatives having catechol moieties. J Antibiot (Tokyo). 1986 Feb;39(2):230-41. PMID:3082839

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_429"

@@ Line 3: / Line 3: @@
 <!-- INSERT YOUR SCENES AND TEXT BELOW THIS LINE -->
-=='''YourMacromolecule'''==
+==''Penicillin binding protein/lactivicin (inhibitor) (2jch)<ref>PMID: 17676039 </ref>''==
+by Tyler Carpenter, Samuel Pierce, Hyunjoon Choi, Anton El Khoury and Tiankai Zhang
-===Introduction===
+[[Student Projects for UMass Chemistry 423 Spring 2016]]
+<StructureSection load='2jch' size='350' side='right' caption='Key player in cell rescue from the imminent death (2jch)' scene='48/483886/Rainbow/1'>
-<Structure load='1m4u' size='200' frame='true' align='right' caption='Insert caption here' scene='Insert optional scene name here' />
+==Introduction==
+Every bacteria wants to live. Every bacteria wants to reproduce. To achieve both, bacteria need some sort of protection that will maintain the structure inside and will protect it from outside dangers. This protection is called cell wall, that primarily consists of a polymer that is called peptidoglycan. This compound can be synthesized only with the help of <font color='red'> ''penicillin binding proteins (PBPs)'' </font> , which are the target of this article (the name basically comes from a way it was discovered). PBP serves as a catalyst in the final stages of peptidoglycan synthesis, transglycosylation and transpeptidation in particular.<ref>PMID: 23949602</ref>  Although there are multiple types of PBPs, they all bind penicillin (however, with different affinities) and this is what is important for this article.
-<scene name='Sandbox_Reserved_429/Alec_alphas/1'>alpha helices</scene>
+As the bacteria infiltrates the organism, it becomes necessary to somehow destroy it. One way is to to break this cell wall. To achieve this, the penicillin is introduced to the bacteria that later reacts with PBPs (using <font color='orange'> ''β-lactam ring'' </font>), preventing it from catalyzing the formation of a peptidoglycan and, as a result, stops the formation of a cell wall. However, many pathogenic bacteria have evolved a way to mutate themselves to be immune to various drugs that contain this β-lactam rings. What happens is that bacterium produces enzyme, called <scene name='48/483886/Beta_lactamase/1'>β-lactamase</scene> that cleaves the β-lactam ring on a penicillin and thus preventing it from reacting with PBPs. To solve this problem, the new drug, called, lactivicin was developed that contains gamma-lactone rings and cycloserine as substitutions to β-lactam. So far, it has proved to be an efficient antibiotic. It successfully binds to PBPs and prevents cell wall from forming.
+Recently, an analog of lactivicin, phenoxylactivicin (PLTV) was developed and is discussed in this article.
-Bone Morphogenetic Protein 7 (BMP-7) is a protein that is involved in a variety of aspects of embryonic and adult development. Some of the areas it is involved in are neural tissue induction, the formation of bones and joints in the skeletal system, and neurogenesis in the adult brain.
+The complex of the PBP with <scene name='48/483886/Pltv/3'>phenoxylactivicin</scene> is shown on the picture.
-Neural induction is the process by which the undifferentiated ectoderm layer of the embryo are signaled to form neuro-ectoderm cells by the mesoderm. These differentiated cells will become neural cells. Only some of the cells are signaled to differentiate in this way, and the rest become the epidermis.
-In bone formation, first a flexible membrane is formed in the embryo that develops into cartilage. As the embryo develops, signaling through proteins in the BMP family including BMP-7 causing ossification to occur, which is the process of forming bone, replacing the cartilage membranes. This can be seen in the development of the skull.  BMP can also signal for cartilage to transform to bone, which is how much of the rest of the skeleton develops.
-One of the most important aspects of BMP-7 is its role in neurogenesis in the adult brain. Neurogenesis is the process by which new neurons are created in the adult brain. Initially it was thought that proteins in the BMP family would inhibit neurogenesis unless deactivated by the antagonist, Noggin. But when the levels of neurogenesis were examined with the over expression and signalling of BMP, there was no inhibition of the creation of neurons. In fact further  research has shown that BMP-mediated signalling is required to allow neurogenesis in adults.
-Because BMP’s are crucial in much of the development and upkeep of many organs and systems, there are many disease that can arise or be affected by dysfunctional BMP genes and proteins. The incorrect implementation of BMP-7 during development can result in issues with skeletal and neural development. BMP-7 can also have impacts after the initial fetal development. Research has linked a lack of BMP-7 signalling to the progression of gastrointestinal cancers, particularly colon and esophageal cancer.
+Picture on the right is displayed as N-terminus to C-termiunus Rainbow for<scene name='48/483886/Rainbow/1'> PBP complex </scene>.  The coloring goes as shown on the sample:
+<blockquote>
+{{Template:ColorKey_Amino2CarboxyRainbow}}
-There have also been developments in using BMP’s as therapeutics. Because the main role of BMP’s is bone formation, one of the most promising areas is in bone reformation after injury. BMP-7 and BMP-2 have been successfully adapted and used in combination with bone grafts during surgery, and have been extremely useful in spinal cervical fusion.
-While these therapeutics are great developments, there is still much more potential because of the effects of BMP on the whole body. Currently, research is being conducted to understand how BMP-7 can be used in treating chronic kidney disease. And because of the ability to regulate neurogenesis, it is possible that BMP proteins can be used in the treatment or cure of neurodegenerative diseases such as Alzheimer's.
-===Overall Structure===
+==Overall Structure==
-<Structure load='1m4u' size='200' frame='true' align='right' caption='Insert caption here' scene='Insert optional scene name here' />
+Penicillin Binding Proteins have specific structures and designs that promote allow the binding of Penicillin and other antibiotics. One of the enzymes within the PBP family is <scene name='48/483886/D-alanyl-d-alanine_carboxypept/1'>D-alanyl-D-alanine carboxypeptidase/transpeptidase</scene>. This enzyme is responsible for the link between two chains in the peptidoglycan network <ref> Goodsell, David. "Penicillin-binding Proteins." Penicillin-binding Proteins. May 2002. Web. 07 Apr. 2016.</ref>. DA-DA peptidase’s structure contains a serine in the active site. Ser 62 is used to bind a peptide strand which would then link to another strand of the network, and this is the site where penicillin binds and inhibits the protein.
-Draft
+	This enzyme is split into two sections, which will be referred to as the North and South regions. The North Region contains both the carboxyl and amino termini, two α-helices, and a nine-stranded antiparallel β-sheet <ref> Kelly, J. A., and A. P. Kuzin. "3PTE." RCSB PDB. Web. 07 Apr. 2016.</ref> This leads the Northern region of the enzyme to appear symmetrical. Both termini lead are connected to helices and then into β-strands. Inbetween the sets of strands the South region of the peptide is formed and this is strictly made out of helices. In the center of the two regions is where the Ser 62 active site resides, and this is also at the symmetrical center of the protein. The protein essentially forms a cupped hand, with the center of the palm being the active site, the bottom of the palm being a series of 8 or so helices, the knuckles being the β-strands, and the tips of the fingers being the two helices of the North region.
-BMP-7 has a variety of structural characteristics. First and foremost are the two distinct domains which form the dimer. These are AC1 an AC2. They can be seen in red (AC1) and green(AC2) (<scene name='Sandbox_Reserved_429/Dimer/1'>TextToBeDisplayed</scene>). Notice how they are interacting but are not bound at the interface.
-. AA distribution
-Another important attribute to view in BMP-7 is the location and number of the alpha helices. They can be seen here <scene name='Sandbox_Reserved_429/Secondary_structure_highlight/1'>Secondary Structures Highlighted</scene>.
+==Binding Interactions==
-. Other pieces (non AA)
-. Primary Structure? Secondary? Tertiary?
+The final stages of the synthesis of peptidoglycan requires penicillin binding proteins. All bacterial cell walls are made of peptidoglycan and it is important to note that all bacteria have reactions that covalently link the first peptidoglycan between two polysaccharides. This reaction is catalyzed by transpeptidase enzymes which is inhibited by the beta-lactam. Penicillin binding protein binds to beta-lactam antibiotics because they are similar in chemical structure to the modular pieces that form the peptidoglycan. The <scene name='48/483886/betalactem/2'>beta-lactam</scene> amide bond is ruptured to form a covalent bond with the catalytic serine at the binding protein's active site. When the PBP form a stable covalent complex with the beta-lactam antibiotics, the cell dies due to PBP inactivation.
-===Binding Interactions===
+The beta-lactam area in most drugs resemble the D-Ala-D-Ala end of peptides to which the transpeptidase enzyme binds. At the DA-DA, there is a serine 62 which is used to bind peptide strands to other stands and this is also where penicillin binds and inhibits the protein. When the transpeptidase reaction takes place, the enzymes bind to the DA-DA end of the chain which results in one of the DA residues to be released and the enzyme attaches to the end of the peptide. Next, the closest peptidoglycan is covalently linked to the first peptidoglycan which forms a crosslink between the two polysaccharides. Almost every bacterium has PBP genes but most enzymes are inhibited by the beta-lactams. The enzymes become inactive due to the drugs binding tightly to the active site and blocking the reaction.
-<Structure load='1m4u' size='500' frame='true' align='right' caption='BMP-7 Complexed with noggin displayed of active binding sites' scene='Insert optional scene name here' />
+==Additional Features==
-<scene name='Sandbox_Reserved_429/Whole/1'>Noggin-BMP-7 Complex</scene>
+Antibiotics resistance is the property of bacteria that have receive relatively low effectiveness by antibiotic. With the overproduction and overusing of antibiotics, more bacteria have low resistance to antibiotic are killed than the bacteria have high resistance. Under the evolutionary pressure, the remaining group of bacteria have relatively high resistance which means that the normal antibiotics have less effectiveness or do not have effectiveness anymore. As penicillin-binding proteins playing an important role at bacteria’s cell synthesis and β-lactams antibiotics inhibiting bacterial division by binding penicillin-binding proteins, antibiotics resistance also emerges to the penicillin-binding proteins and makes penicillin-binding proteins have low affinity for penicillins.
+Normally, the bacteria produce the penicillin binding proteins with low penicillin-affinity <scene name='48/483886/Conserved_residues_of_pbp/2'>low affinity</scene> by transformation, which is a kind of gene modification. Through this way, bacteria could have a relatively higher resistance to β-lactams antibiotics. But staphylococcus is a special case, it strengthens the drug resistance by two ways instead of gene exchange. By the raised dissociation constants for the non-covalent pre-acylation and the dropped penicillin-sensitive microscopic rate constant for acylation, staphylococcus enhance its own drug resistance.<ref>PMID:15226303</ref>
-Draft
+And the solution to the penicillin binding proteins drug resistance could be semi-synthetic β-lactams. The mechanism is that semi-synthetic β-lactams have the alternative side chain compared to the normal penicillins and it will make penicillin binding proteins have the higher affinity to it and as a result the increasing drug resistance will be solved.<ref>PMID:3082839</ref>
-BMP-7 uses two pairs of antiparallel <scene name='Sandbox_Reserved_429/Free_bmp_labeled/1'>β-strands</scene> referred as <span style="color:green">'''Finger 1'''</span> and <span style="color:orangered">'''Finger 2'''</span> for binding activities. The curvature of the fingers creates a site in which the α3 of the other subunit binds to stabilize the
+==Quiz Question 1==
-<scene name='Sandbox_Reserved_429/Unbounded_bmp7/1'>dimer</scene>. Free BMP-7 shows <scene name='Sandbox_Reserved_429/Knuckles_wrist_free/1'>conformational</scene> <scene name='Sandbox_Reserved_429/Confirmational/2'>changes</scene> in the "<span style="color:deepskyblue">'''wrist'''</span> " and "<span style="color:darkviolet">'''knuckles'''</span>" areas upon complexing with receptors and antagonist proteins. [A]
-<scene name='Sandbox_Reserved_429/Signaling/1'>Signaling</scene> by BMP-7 occurs by the binding of  the protein to high affinity type II receptor (at the <span style="color:darkviolet">'''knuckles'''</span> epitope) follow by the recruitment of the low affinity type I receptor (at the "<span style="color:deepskyblue">'''wrist'''</span> " epitope). The binding causes the trans-phosphorylation of the Type I receptor at a a glycine- and serine- rich region (GS-Box) by the type II receptor kinase. Afterwards the type I receptor Ser/Thr-kinase activates leading to intracellular signaling.  [C]
+The binding pocket for PTLV (all residues within 5Å of the molecule) is shown <scene name='48/483886/Pltv_binding_pocket/1'>here</scene> colored from most conserved to most variable.
-Bone morphogenetic proteins (BMPs)are regulated by the binding of three classes of antagonist inhibitory proteins: Noggin; the DAN family; and verterbrate Chordin and Drosophila SOG. Noggin is a homologous BMP-specific anatagonist protein found to regulate the dorsal structures in ventralized Xenopus embryos. The structure of the C-terminal half of the Noggin resembles the BMPs in that it have two pairs of antiparallel β-strands extending out from a core containing disulphides bonds. In contrast to BMP-7, binding of the monomer consists of interaction between the α4 of each monomer. When noggin binds to BMP-7, the tip of finger 1 and 2 in BMP-7 curls around the N-terminal segment of the noggin. [A]
+{{Template:ColorKey_ConSurf}}
-BMP ligands have two prominent hydrophobic patches for receptor binding interfaces: convex type II and concave type I. Superposition of the noggin-BMP-7 structure show the masking of both pairs of binding epitopes. The obstruction of the type I receptor-binding occurs due to hydrophobic interactions. The hydrophobic ring of Pro 35 of the noggin inserts into the hydrophobic pocket on BMP-7 formed by Trp 52, Trp 55, Val 87, Tyr 128, and Met 131. In contrast, the type II receptor-binding is obstructed by the C-terminal half of the clip segment by the distal tip of finger 1 and by finger 2.  [A]
+Why are most of these residues highly conserved?
-In summary, the binding of noggin to BMP-7 consists of a hydrophobic side chain from the backbone insetred into the hydrophobic pocket of BMP followed by complementary interactions between two curved hydrophobic surfaces.
+Would it be evolutionarily advantageous to mutate this binding pocket to prevent inhibition by PTLV? Explain.
-Follistatin is a proposed BMP antagonist which is present in embryonic muscle cells. The BMP antagonist enhances the BMP-7 action for muscle grwoth but it prevents the induction of apoptosis and muscle loss. The antagonist protein interacts directly with BMP but does not prevent the ligan from binding to its receptors resulting in a trimeric complex. [B]
-===Additional Features===
-<Structure load='1m4u' size='200' frame='true' align='right' caption='Insert caption here' scene='Insert optional scene name here' />
-. Mutations in NOG
+==See Also==
+*[[Penicillin-binding protein]]
+*[[2y2g]]
+*[[2bg1]]
+*[[2fff]]
+*[[2jch]]
-a.Substitutions of six
+==Credits==
-positions :Pro35Arg, Cys184Tyr, Gly189Cys, Ile220Asn, Tyr222Cys/
-Tyr222Asn, Pro223Leu
-affect folding stability
-b. Pro35Arg - decreased affinity, diminished inhibition of chondrogenesis
+Introduction - Anton El Khoury
-c. Pro35Ser- similar
+Overall Structure - Tyler Carpenter
-. BMP regulators evolution
+Drug Binding Site - Hyunjoon Choi
--BMP signalling pathway, gene duplication ligand receptor
-- structural homology between agonists and antagonists
-===Credits===
+Additional Features - Tiankai Zhang
-Introduction - Alec
+Quiz Question 1 - Samuel Pierce
-Overall Structure - William
+==References==
-Drug Binding Site - Felix
-Additional Features - Paula
-===References===
 <references/>
-[A]Groppe J, Greenwald J, Wiater E, Rodriguez-Leon J, Economides AN, Kwiatkowski W, Affolter M, Vale WW, Belmonte JC, Choe S. Structural basis of BMP signalling inhibition by the cystine knot protein Noggin. Nature. 2002 Dec 12;420(6916):636-42. PMID:12478285 doi:10.1038/nature01245
-[B]Floriani, C., and F. Calderazzo. "Oxygen Adducts of Schiff's Base Complexes of Cobalt Prepared in Solution." Journal of the Chemical Society A: Inorganic, Physical, Theoretical (1969): 946-53. Print.
-[C]Sebald, Walter, and Thomas D. Mueller. "The Interaction of BMP-7 and ActRII Implicates a New Mode of Receptor Assembly." Trends in biochemical sciences 28.10 (2003): 518-21. Print.

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Penicillin binding protein/lactivicin (inhibitor) (2jch)^[1]

Contents

Introduction

Overall Structure

Binding Interactions

Additional Features

Quiz Question 1

See Also

Credits

References

Views

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Sandbox Reserved 429

From Proteopedia

Current revision

Penicillin binding protein/lactivicin (inhibitor) (2jch)[1]

Contents

Introduction

Overall Structure

Binding Interactions

Additional Features

Quiz Question 1

See Also

Credits

References

Views

Personal tools

Navigation

Search

Toolbox

Penicillin binding protein/lactivicin (inhibitor) (2jch)^[1]