Chemistry:Dipalmitoylphosphatidylcholine

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Dipalmitoylphosphatidylcholine
Dipalmitoylphosphatidylcholine.svg
Names
IUPAC name
1,2-Dipalmitoylphosphatidylcholine
Identifiers
3D model (JSmol)
ChemSpider
UNII
Properties
C40H80NO8P
Molar mass 734.053 g·mol−1
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

Dipalmitoylphosphatidylcholine (DPPC) is a phospholipid (and a lecithin) consisting of two C16 palmitic acid groups attached to a phosphatidylcholine head-group.

It is the main constituent of pulmonary surfactants, which reduces the work of breathing and prevents alveolar collapse during breathing. It also plays an important role in the study of liposomes and human bilayers.[2][3]

Lung surfactant

Lung surfactant (LS) is a surface-active material produced by most air-breathing animals for the purpose of reducing the surface tension of the water layer where gas exchange occurs in the lungs, given that the movements due to inhalation and exhalation may cause damage if there is not enough energy to sustain alveolar structural integrity.

The monolayer formed by the LS on the interface is composed primarily of phospholipids (80%), in addition to proteins (12%) and neutral lipids (8%). Among the phospholipids, the most prevalent one is phosphatidylcholine (PC, or lecithin) (70–85%), which in turn is the basis of a pool of similar diacylphophatidylcholines of which 50% is dipalmitoylphosphatidylcholine or DPPC.[4]

While DPPC itself already has the ability to reduce the surface tension of the alveolar liquid, the proteins and other lipids in the surfactant further facilitate the adsorption of oxygen into the air-liquid interface.

DPPC is a variant of phosphatidylcholine. Its structure includes both a hydrophilic "head" and hydrophobic "tails", and it is this arrangement that makes it able to reduce the surface tension of the water layer. The choline radical constitutes the polar hydrophilic head; it is oriented towards and extends into the alveolar liquid. The palmitic acid (C16) chains form the nonpolar hydrophobic tails; these are oriented towards the outer side.

Biosynthesis

The synthesis of the phospholipids contained in pulmonary surfactant takes place in the endoplasmic reticulum of type II pneumocytes. Pulmonary surfactant has both protein and lipid components. More specifically, it has been found that phosphatidylcholine (PC) is the most abundant phospholipid (70%–85%), and that PC is primarily present as dipalmitoylphosphatidylcholine (DPPC).

De novo synthesis of phosphatidylcholine in the lung arises primarily from cytidine diphosphate-choline (CDP-choline). The transformation of CDP-choline to phosphatidylcholine is effected by choline phosphate cytidyltransferase. Under certain conditions the enzymes choline kinase, glycerol-3-phosphate acyltransferase and phosphatidate phosphatase may play regulatory roles.

Of the total DPPC in the pulmonary surfactant, 45% comes from de novo biosynthesis. The rest is formed by transacylation mechanisms that exchange palmitoyl groups for the unsaturated acyl chains of other related diacylphosphatidylcholines.[5] Removal of the acyl chains from these related compounds produces lysophosphatidylcholine; reacylation with palmitoyl-CoA is then facilitated by lysophosphatidylcholine acyltransferase to form DPPC.

Characteristics

A laminar system consisting of water and gas molecules separated by DPPC lipid layers
A single time-point "snapshot" of a molecular dynamics simulation of DPPC lipid bilayer formation in a two phase system. DPPC (color elements) interacts with water molecules (transparent part) in the image.

Temperature

This phospholipid is found in a solid/gel phase at 37 °C (at the effective temperature of the human body). Its melting point is around 41.3 °C. Therefore, when the temperature is above 41 °C, DPPC is no longer found in a gel phase but in a liquid one.[6]

When in contact with silica surfaces, it has been demonstrated that DPPC bilayers have different properties depending on the temperature.

Layer thickness remains the same at 25 °C and at 39 °C. However, when the temperature is further increased to 55 °C, the DPPC bilayer structure changes significantly, which causes a decrease in the layer thickness. The reason for this trait is that, in fact, at 55 °C DPPC is found in a disordered liquid state, whereas at a lower temperature it is found in a more-ordered gel state.

Temperature affects the layer's roughness too, which starts to change slightly when temperature is lowered to 25 °C.

Finally, the load-bearing capacity of the bilayer is higher when the temperature exceeds the phase transition temperature (due to its increased fluidity). When this molecule is found in a liquid state, where the fluidity is much higher, it is thought that the bilayer also develops a self-healing capacity.[7]

Amphipathic behaviour

Simple Diagram showing surfactant's function in stopping the collapse of the alveoli when exhaling

DPPC is an amphipathic lipid. This characteristic is due to its hydrophilic head, composed of the polar phosphatidylcholine group, and its hydrophobic tails, formed by two nonpolar palmitic acid (C16) chains. This trait allows DPPC to easily and spontaneously form micelles, monolayers, bilayers and liposomes when it is in contact with a polar solvent.

Surfactant

DPPC is the main phospholipid of pulmonary surfactant, and it is surface-active due to its amphipathic behaviour and its adsorption capacity.[8] However, adsorption is not optimal at human body temperature for DPPC alone, because at 37 °C it is found in a gel phase. The presence of some unsaturated phospholipids (such as dioleoylphosphatidylcholine [DOPC] or phosphatidylglycerol) and cholesterol increases the surfactant's fluidity, so it can adsorb oxygen more efficiently.[9] When this mixture contacts water, for example, it accumulates at the water-air interface and forms a thin superficial pellicule of surfactant. The polar heads of the molecules composing the surfactant are attracted by the polar molecules of the liquid (in this case, H2O molecules), causing a significant diminution of the water's surface tension.

Current uses

Research uses

DPPC is usually used for research purposes, such as creating liposomes and bilayers which are involved in bigger studies. The Langmuir–Blodgett technique allows the synthesis of liposomal DPPC bilayers. Currently, these liposomes are used in the study of the properties of this phosphatidylcholine and of its use as a mechanism of drug delivery in the human body.

Furthermore, because vesicle fusion dynamics are different for lipids in the gel phase versus the fluid phase, it allows scientists to use DPPC along with DOPC in Atomic Force Microscopy and Atomic Force Spectroscopy.[10][11]

Pharmaceutical uses

Dipalmitoylphosphatidylcholine (DPPC) is routinely used to formulate some medicines used for treatment of respiratory distress syndrome (RDS) in newborns. Current synthetic surfactants are combinations of DPPC along with other phospholipids,[12] neutral lipids and lipoproteins.

The treatment of preterm infants with RDS using surfactants was initially developed in the 1960s, and recent studies have demonstrated an improvement in clinical outcomes.[13] The first treatment given to some newborns with RDS was surfactant phospholipids, specifically DPPC, by means of an aerosol (Robillard, 1964).[full citation needed] This treatment proved ineffective because administration of DPPC alone did not provide any beneficial effects. Subsequently, studies were carried out to find more effective drugs for treatment of this disease.

Pulmonary surfactants can be classified into three types:[14]

The first generation of protein-free synthetic surfactants contained only DPPC. The best known is colfosceril palmitate.[14]

The second generation of surfactants were of natural (animal) origin, and were obtained from the lungs of cattle or pigs. The surfactants extracted from bovine lungs were Infasurf and Alvofact, the porcine lung extracts included Curosurf, and those made from modified bovine lung extracts included Survanta or Beraksurf (Beractant). Unlike newborns with RDS that were administered first-generation drugs, those that were treated with these second-generation surfactants required less oxygen and ventilatory support within 72 hours of drug administration.

The third generation of surfactants incorporates synthetic peptides or recombinant proteins. These use a mixture of different components. DPPC is the agent used to decrease surface tension, and the rest of the components help increase oxygen adsorption. The best known are Venicute and Surfaxin.[14] These drugs are still under development, so there is as yet no evidence as to whether they possess advantages compared to the second-generation preparations.

DPPC is also used to form liposomes that are used as components of drug delivery systems.[15]

DPPC-related illnesses

Surfactant Dysfunction Disorder is a disease that affects newborn children whose pulmonary surfactant is insufficient for adequate breathing, resulting in respiratory distress syndrome (RDS).[16]

Despite DPPC being one of the major components of lung surfactant, most of the genetic errors that are linked with surfactant dysfunction disorder are not linked to DPPC. Rather, the main causes of this disease are differences in the production of surfactant proteins B and C due to genetic abnormalities.

However, there is a genetic condition that is related to DPPC which causes a deficiency in the production of ABCA1 protein. This protein is crucial in the transport of phospholipids – and therefore DPPC – to the lamellar bodies of the alveolar cells, where DPPC interacts with surfactant proteins to form pulmonary surfactant.[17]

Current studies cannot find a correlation between the percentage of DPPC in lung surfactant and the age of gestation, although a proven relationship has been found between the percentage of DPPC and POPC (palmitoyl-oleoyl phosphatidylcholine) in babies with respiratory distress syndrome compared with babies without this condition. These connections suggest that a particular surfactant composition will lead to respiratory distress syndrome, regardless of gestational age.

The correlation between DPPC percentage and respiratory distress syndrome is why DPPC is used to make drugs to treat newborn infants with the disease.[18]

In addition, DPPC has been shown to be related to infection of polarized cells by a specific kind of human adenovirus (HAdV-C2). Some studies have indicated that disaturated DPPC boosts infection of A59 cells with HAdV-C2 (possibly by permitting virus entry via the apical side of polarized cells).[19]

References

  1. Smith, Ross; Tanford, Charles (June 1972). "The critical micelle concentration of l-α-dipalmitoylphosphatidylcholine in water and water/methanol solutions". Journal of Molecular Biology 67 (1): 75–83. doi:10.1016/0022-2836(72)90387-7. PMID 5042465. 
  2. Hu, Q; Hossain, S; Joshi, R P (2018-06-25). "Analysis of a dual shock-wave and ultrashort electric pulsing strategy for electro-manipulation of membrane nanopores" (in en). Journal of Physics D: Applied Physics 51 (28): 285403. doi:10.1088/1361-6463/aaca7a. ISSN 0022-3727. Bibcode2018JPhD...51B5403H. https://iopscience.iop.org/article/10.1088/1361-6463/aaca7a. 
  3. Hossain, Shadeeb; Abdelgawad, Ahmed (2020-01-02). "Analysis of membrane permeability due to synergistic effect of controlled shock wave and electric field application". Electromagnetic Biology and Medicine 39 (1): 20–29. doi:10.1080/15368378.2019.1706553. ISSN 1536-8378. PMID 31868023. https://doi.org/10.1080/15368378.2019.1706553. 
  4. Stachowicz-Kuśnierz, Anna; Seidler, Tomasz; Rogalska, Ewa; Korchowiec, Jacek; Korchowiec, Beata (2020-02-01). "Lung surfactant monolayer – A good natural barrier against dibenzo-p-dioxins". Chemosphere 240: 124850. doi:10.1016/j.chemosphere.2019.124850. ISSN 0045-6535. PMID 31561163. Bibcode2020Chmsp.240l4850S. 
  5. Fernández Ruano, D. Miguel Luis (2000). Caracterización del complejo surfactante pulmonar: Estudio de la estructura y función de la proteína A (SP-A).. Madrid: Universidad Complutense de Madrid. pp. 10–11. https://eprints.ucm.es/3560/1/T24398.pdf. 
  6. "Dipalmitoylphosphatidylcholine - an overview | ScienceDirect Topics". https://www.sciencedirect.com/topics/biochemistry-genetics-and-molecular-biology/dipalmitoylphosphatidylcholine. 
  7. Wang, Min; Zander, Thomas; Liu, Xiaoyan; Liu, Chao; Raj, Akanksha; Florian Wieland, D. C.; Garamus, Vasil M.; Willumeit-Römer, Regine et al. (2015-05-01). "The effect of temperature on supported dipalmitoylphosphatidylcholine (DPPC) bilayers: Structure and lubrication performance". Journal of Colloid and Interface Science 445: 84–92. doi:10.1016/j.jcis.2014.12.042. ISSN 0021-9797. PMID 25596372. Bibcode2015JCIS..445...84W. 
  8. Bai, Xuan; Xu, Lu; Tang, Jenny Y.; Zuo, Yi Y.; Hu, Guoqing (2019-10-01). "Adsorption of Phospholipids at the Air–Water Surface". Biophysical Journal 117 (7): 1224–1233. doi:10.1016/j.bpj.2019.08.022. ISSN 1542-0086. PMID 31519299. Bibcode2019BpJ...117.1224B. 
  9. Jackson, J. Craig (2012-01-01), Gleason, Christine A.; Devaskar, Sherin U., eds., "Chapter 46 - Respiratory Distress in the Preterm Infant", Avery's Diseases of the Newborn (Ninth Edition) (W.B. Saunders): pp. 633–646, ISBN 9781437701340, http://www.sciencedirect.com/science/article/pii/B9781437701340100460, retrieved 2019-10-25 
  10. Panzuela, S.; Tieleman, D. P.; Mederos, L.; Velasco, E. (2019-10-22). "Molecular Ordering in Lipid Monolayers: An Atomistic Simulation". Langmuir 35 (42): 13782–13790. doi:10.1021/acs.langmuir.9b02635. ISSN 0743-7463. PMID 31553617. Bibcode2019arXiv190306659P. 
  11. Attwood, Simon J.; Choi, Youngjik; Leonenko, Zoya (2013-02-06). "Preparation of DOPC and DPPC Supported Planar Lipid Bilayers for Atomic Force Microscopy and Atomic Force Spectroscopy". International Journal of Molecular Sciences 14 (2): 3514–3539. doi:10.3390/ijms14023514. ISSN 1422-0067. PMID 23389046. 
  12. Athenstaedt, K. (2010). "Neutral Lipids in Yeast: Synthesis, Storage and Degradation". Handbook of Hydrocarbon and Lipid Microbiology. pp. 471–480. doi:10.1007/978-3-540-77587-4_35. ISBN 978-3-540-77584-3. 
  13. Soll, Roger; Ozek, Eren (2010-01-20). "Prophylactic protein free synthetic surfactant for preventing morbidity and mortality in preterm infants". The Cochrane Database of Systematic Reviews 2010 (1): CD001079. doi:10.1002/14651858.CD001079.pub2. ISSN 1469-493X. PMID 20091513. 
  14. 14.0 14.1 14.2 Chattás, Lic. Guillermina (October 2013). "Administración de surfactante exógeno". Revista Enfermería Neonatal Nº 16: 10–17. http://fundasamin.org.ar/newsite/wp-content/uploads/2014/01/Administraci%C3%B3n-de-surfactante-ex%C3%B3geno.pdf. 
  15. Li, Jing; Wang, Xuling; Zhang, Ting; Wang, Chunling; Huang, Zhenjun; Luo, Xiang; Deng, Yihui (2015). "A review on phospholipids and their main applications in drug delivery systems". Asian Journal of Pharmaceutical Sciences 10 (2): 81–98. doi:10.1016/j.ajps.2014.09.004. 
  16. Reference, Genetics Home. "Surfactant dysfunction" (in en). https://ghr.nlm.nih.gov/condition/surfactant-dysfunction. 
  17. Reference, Genetics Home. "ABCA3 gene" (in en). https://ghr.nlm.nih.gov/gene/ABCA3. 
  18. Ashton, M. R.; Postle, A. D.; Hall, M. A.; Smith, S. L.; Kelly, F. J.; Normand, I. C. (April 1992). "Phosphatidylcholine composition of endotracheal tube aspirates of neonates and subsequent respiratory disease". Archives of Disease in Childhood 67 (4 Spec No): 378–382. doi:10.1136/adc.67.4_spec_no.378. ISSN 1468-2044. PMID 1586174. 
  19. Luisoni, Stefania; Greber, Urs F. (2016-01-01), Curiel, David T., ed., "2 - Biology of Adenovirus Cell Entry: Receptors, Pathways, Mechanisms", Adenoviral Vectors for Gene Therapy (Second Edition) (Academic Press): pp. 27–58, ISBN 9780128002766, http://www.sciencedirect.com/science/article/pii/B9780128002766000024, retrieved 2019-10-25